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Morvan’s Syndrome, or Morvan’s fibrillary chorea (MFC), is a rare autoimmune disease named after nineteenth century French physician Augustin Marie Morvan. “La chorée fibrillaire” was first coined by Morvan in 1890 when describing patients with multiple, irregular contractions of the long muscles, cramping, weakness, pruritis, hyperhidrosis, insomnia, and delirium.  It normally presents with a slow insidious onset over months to years.  90% of cases spontaneously go into remission, while the other 10% of cases lead to death. 
Overview[edit | edit source]
In 1890, Morvan described a patient with myokymia (muscle twitching) associated with muscle pain, excessive sweating, and disordered sleep.  This rare disorder is characterized by severe insomnia, amounting to no less than complete lack of sleep (agrypnia) for weeks or months in a row, and associated with autonomic alterations consisting of profuse perspiration with characteristic skin Miliaria (miliaria rubra, sweat rash or prickly heat), tachycardia, increased body temperature, and hypertension. Patients display a remarkable hallucinatory behavior, and peculiar motor disturbances, which Morvan reported under the term “fibrillary chorea” but which are best described nowadays as neuromyotonic discharges.  The association of the disease with thymoma, tumour, autoimmune diseases, and autoantibodies suggests an autoimmune or paraneoplastic aetiology.  Besides an immune-mediated etiology, it is also believed to occur in gold, mercury, or manganese poisoning. 
Prevalence[edit | edit source]
There are only about 14 reported cases of Morvan’s Syndrome in the English Literature.  With only a limited number of reported cases, the complete spectrum of the Central Nervous System (CNS) symptomatology has not been well established.  The natural history of Morvan’s is highly variable. Two cases have been reported to remit spontaneously. Others have required a combination of plasmapheresis and long term immunosupression, although in one of these cases the patient died shortly after receiving Plasma Exchange (PE). Other fatalities without remission have been described by, amongst others, Morvan himself. 
Symptoms and clinical signs[edit | edit source]
General Symptoms[edit | edit source]
In one of the few reported cases, the subject presented with muscle weakness and fatigue, muscle twitching, excessive sweating and salivation, small joint pain, itching and weight loss. The subject also developed confusional episodes with spatial and temporal disorientation, visual and auditory hallucinations, complex behavior during sleep and progressive nocturnal insomnia associated with diurnal drowsiness. There was also severe constipation, urinary incontinence, and excessive lacrimation. When left alone, the subject would slowly lapse into a stuporous state with dreamlike episodes characterized by complex and quasi-purposeful gestures and movements (enacted dreams). Marked hyperhidrosis and excessive salivation were evident. Neurological examination disclosed diffuse muscle twitching and spontaneous and reflex myoclonus, slight muscle atrophy in the limbs, absence of tendon reflexes in the lower limbs and diffuse erythema especially on the trunk with scratching lesions of the skin. 
Insomnia[edit | edit source]
In all of the reported cases, the need for sleep was severely reduced and in some cases not necessary. The duration of sleep in one case decreased to about 2-4 hours per 24 hour period.  Clinical features pertaining to insomnia include daytime drowiness associated with a loss of ability to sleep, intermingled with confusional oneiric status, and the emergence of atypical REM sleep from wakefulness. The Polysomnogram (PSG) picture of this disease is characterized by an inability to generate physiological sleep (key features are the suppression of the hallmarks of stage 2 non-REM sleep: spindles and K complexes) and by the emergence of REM sleep without atonia. The involvement of the thalamus and connected limbic structures in the pathology indicate the prominent role that the limbic thalamus plays in the pathophysiology of sleep.  In a case documented in 1974, PSG findings documented the sustained absence of all sleep rhythms for up to a period of 4 months. 
Electroencephalography (EEG) in one case was dominated by “wakefulness” and “subwakefulness” states alternating or intermingled with short (< 1 min) atypical REM sleep phases, characterized by a loss of muscle atonia. The “subwakefulness” state was characterized by 4-6 Hz theta activity intermingled with fast activity and desynchronized lower voltage theta activity, behaviourally associated with sleep-like somatic and autonomic behavior. The subject was said to suffer from “agrypnia excitata”, which consists of severe total insomnia of long duration associated with decreased vigilance, mental confusion, hallucinations, motor agitation, and complex motor behavior mimicking dreams, and autonomic activation. CNS and autonomic symptoms were caused by impaired corticolimbic control of the subcortical structures regulating the sleep-wake and autonomic functions. 
Neuromyotonia[edit | edit source]
Neuromyotonia refers to muscle twitching and cramping at rest that is exacerbated with exercise. It is caused by sustained or repetitive spontaneous muscle activity of peripheral nerve origin. Myokymia, or spontaneous rippling and twitching movements of muscles, is a visible component of neuromyotonia. Electromyography (EMG) discloses spontaneous, repetitive motor unit or single fiber discharges firing in irregular rhythmic bursts at high intraburst frequencies.  Some of the muscles exhibiting twitching include the bilateral gastrocnemii, quadriceps femoris, biceps brachii, and right masseter.  In vivo electrophysiological studies suggest at least some dysfunction of the muscle cell membrane.  In the examined muscles, no abnormal insertional activity or fibrillation potentials were noted. Nerve conduction studies were normal. 
Other Symptoms[edit | edit source]
Breathing difficulties can occur, resulting from neuromyotonic activity of the laryngeal muscles. Laryngeal spasm possibly resulting from neuromyotonia has been described previously, and this highlights that, in patients with unexplained laryngospasm, neuromytonia should be added to the list of differential diagnoses. 
Studies have shown subtly decreased metabolism on positron emission tomography (PET) and single photon emission computed tomography (SPECT) in the left inferior frontal and left temporal lobes.  Ancillary laboratory tests including MRI and brain biopsy have confirmed temporal lobe involvement. Cranial MRI shows increased signal in the hippocampus. 
Cerebral Spinal Fluid (CSF) shows normal protein, glucose, white blood cell, and IgG index but there are weak oligoclonal bands, absent in the blood. Marked changes in circadian serum levels of neurohormones were also observed. The absence of morphological alterations of the brain pathology, the suggestion of diffusion of IgG into the thalamus and striatum, more marked than in the cortex (consistent with effects on the thalamolimbic system) the oligoclonal bands in the CSF and the amelioration after PE all strongly support an antibody-mediated basis for the condition.  Raised CSF IgG concentrations and oligoclonal bands have been reported in patients with psychosis. Anti-acetylcholine receptors (anti-AChR) antibodies have also been detected in patients with thymoma, but without clinical manifestations of myasthenia gravis.  There have also been reports of non-paraneoplastic limbic encephalitis associated with raised serum VGKC suggesting that these antibodies may give rise to a spectrum of neurological disease presenting with symptoms arising peripherally, centrally, or both. Yet, in two cases, oligoclonal bands were absent in the CSF and serum, and CSF immunoglobulin profiles were unremarkable. 
Voltage Gated Potassium Channels[edit | edit source]
Antibodies against voltage-gated potassium channels (VGKC), which are detectable in about 40% of patients with acquired neuromytonia, have been implicated in Morvan’s pathophysiology. Raised serum levels of antibodies to VGKCs have been reported in three patients with Morvan’s Syndrome. Binding of serum from a patient with Morvan’s Syndrome to the hippocampus in a similar pattern of antibodies to known VGKC suggest that these antibodies can also cause CNS dysfunction. Additional antibodies against neuromuscular junction channels and receptors have also been described. Experimental evidence exists that these anti-VGKC antibodies cause nerve [hyperexcitability]] by suppression of voltage gated K+ outward currents, whereas other, yet undefined humoral factors have been implicated in anti-VGKC antibody negative neuromyotonia.  It is believed that antibodies to the Shaker-type K+ channels (the Kv1 family) are the type of potassium channel most strongly associated with acquired neuromyotonia and Morvan’s Syndrome. 
Whether VGKC antibodies play a pathogenic role in the encephalopathy as they do in the peripheral nervous system is as yet unclear. It has been suggested that the VGKC antibodies may cross the blood-brain barrier and act centrally, binding predominantly to thalamic and striatal neurons causing encephalopathic and autonomic features. 
Prospective Treatment[edit | edit source]
In most of the reported cases, the treatment options were very similar. Plasmapheresis alone or in combination with steroids, sometimes also with thymectomy and azathioprine, have been the most frequently used therapeutic approach in treating Morvan’s Syndrome. However, this does not always work, as failed response to steroids and to subsequently added plasmapheresis have been reported. Intravenous immunoglobulin was effective in one case. 
In one case, the dramatic response to high-dose oral prednisolone together with pulse methylprednisolone with almost complete disappearance of the symptoms within a short period should induce consideration of corticosteroids. 
In another case, the subject was treated with haloperidol (6 mg/day) with some improvement in the psychomotor agitation and hallucinations, but even high doses of carbamazepine given to the subject failed to improve the spontaneous muscle activity. Plasma Exchange (PE) was initiated, and after the third such session, the itching, sweating, mental disturbances, and complex nocturnal behavior improved and these symptoms completely disappeared after the sixth session, with improvement in insomnia and reduced muscle twitching. However, one month after the sixth PE session, there was a progressive worsening of insomnia and diurnal drowsiness, which promptly disappeared after another two PE sessions. 
In another case, the subject was treated with prednisolone (1mg/kg body weight) with carbamazepine, propanolol, and andamitriptyline. After two weeks, improvement with decreased stiffness and spontaneous muscle activity and improved sleep was observed. After another 7-10 days, the abnormal sleep behavior disappeared completely. 
In another case, symptomatic improvement with plasmapherisis, thymectomy, and chronic immunosupression provide further support for an autoimmune or paraneoplastic basis. 
Although thymectomy is believed to be a key element in the proposed treatment, there is a reported case of Morvan’s Syndrome presenting itself post-thymectomy. 
Comorbid Conditions[edit | edit source]
In one case, a patient was diagnosed with both Morvan’s Syndrome and Pulmonary Hyalinizing Granulomas (PHG). PHG are rare fibrosing lesions of the lung, which have central whorled deposits of lamellar collegen. How these two diseases relate to one another is still unclear. 
Similarity to Limbic Encephalitis[edit | edit source]
The symptoms of Morvan’s Syndrome have been noted to bear a striking similarity to limbic encephalitis (LE). These include the CNS symptoms consisting of insomnia, hallucinations, and disorientation, as well as dementia and psychosis. Both entities can be paraneoplastic and associated with thymoma. Recently, VGKC antibodies were found in patients with LE, strengthening the hypothesis that LE and Morvan’s Syndrome may be closely connected.  Varying symptoms may be used to determine which of the two diseases the subject has. Amnesia, seizures, and mesial temporal lobe structural abnormalities are features of LE, whereas myokymia, hyperhydrosis, and insomnia favor Morvan’s Syndrome. 
References[edit | edit source]
- Cottrell, D A, K J Blackmore, P R W Fawcett et al. (2004). Sub-acute presentation of Morvan's syndrome after thymectomy. Journal of Neurology, Neurosurgery, and Psychiatry 75: 1504–1509.
- Plazzi, Giuseppe, Pasquale Montagna, Stefano Meletti, and Elio Lugaresi (2001-10-25). Polysomnographic study of sleeplessness and oneiricisms in the alcohol withdrawal syndrome. Sleep Medicine 3: 279–282.
- Liguori, R., A. Vincent, L. Clover et al. (2001-08-07). Morvan's syndrome: peripheral and central nervous system and cardiac involvement with antibodies to voltage-gated potassium channels. Brain 124: 2417–2426.
- Montagna, P., E. Lugaresi (2002-01-23). Agrypnia Excitata: a generalized overactivity syndrome and a useful concept in the neurophysiopathology of sleep. Clinical Neurophysiology 113: 552–560.
- Loscher, Wolfgang N., Julia Wanschitz, Karlheinz Reiners, and Stefan Quasthoff (2004-03-24). Morvan's Syndrome: Clinical, Laboratory, and in vitro Electrophysiological Studies. Muscle Nerve 30: 157–163.
- Bajaj, B.K., S. Shrestha (2006-10-07). An interesting case report of Morvan's syndrome from the Indian subcontinent. Neurology India 55 (1): 67–69.
- Deymeer, Feza, Sukriye Akca, Gulsen Kocaman et al. (2005-10-25). Fasciculations, Autonomic Symptoms and Limbic Encephalitis: A Thymoma-Associated Morvan's-Like Syndrome. European Neurology 54: 235–237.
- Kleopa, Kleopas A., Lauren B. Elman, Bethan Lang et al. (2006-03-13). Neuromyotonia and limbic encephalitis sera target mature Shaker-type K+ channels: subunit specificity correlates with clinical manifestations. Brain 129: 1570–1584.
- Winger, David I., Peter Spiegler, Terence K. Trow et al. (2007-03-26). Radiology-Pathology Conference: pulmonary hyalinizing granuloma associated with lupus-like anticoagulant and Morvan's Syndrome. Clinical Imaging 31: 264–268.
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