Myasthenia gravis after glioblastoma resection: paraneoplastic syndrome or coincidence? A unique case report and review of the literature.

Paraneoplastic neurological syndromes (PNS) can manifest with every type of malignancy. A well-known syndrome is myasthenia gravis (MG) in combination with thymomas. No association between primary brain tumors and neuromuscular disorders has been described. Here, we present a case of a 65-year-old patient who developed MG, following an uncomplicated, gross-total resection of a glioblastoma. To our knowledge, this is the first case describing the onset of MG during the early postoperative phase after glioblastoma resection. Current criteria of PNS are insufficient when the neurological syndrome is diagnosed at the time of a malignancy or shortly thereafter and should be revisited.

Associated conditions in small fiber neuropathy - a large cohort study and review of the literature.

BACKGROUND AND PURPOSE: Small fiber neuropathy (SFN) is a common disorder leading to neuropathic pain and autonomic symptoms. The objective of this study was to investigate associated conditions in a large cohort of SFN patients and compare the prevalence to healthy individuals. METHODS: A total of 921 patients with pure SFN were screened according to a standardized comprehensive diagnostic algorithm and compared with literature findings. RESULTS: No associated condition could be found in 53% of the patients. Autoimmune diseases, sodium channel gene mutations, diabetes mellitus including glucose intolerance, and vitamin B12 deficiencies were more prevalent than reported literature findings, followed by alcohol abuse, chemotherapy, monoclonal gammopathy of undetermined significance, and haemochromatosis. In patients who were already known with a possible underlying condition at screening, additional underlying conditions were still found in another 26.7% of patients. CONCLUSIONS: Based on these results, it is recommended that patients with pure SFN are screened at least for autoimmune diseases, sodium channel gene mutations, diabetes mellitus including glucose intolerance, and vitamin B12 deficiency, even when they already have a potential underlying condition at referral.

Genetic aspects of sodium channelopathy in small fiber neuropathy.

Small fiber neuropathy (SFN) is a disorder typically dominated by neuropathic pain and autonomic dysfunction, in which the thinly myelinated Aδ-fibers and unmyelinated C-fibers are selectively injured. The diagnosis SFN is based on a reduced intraepidermal nerve fiber density and/or abnormal thermal thresholds in quantitative sensory testing. The etiologies of SFN are diverse, although no apparent cause is frequently seen. Recently, SCN9A-gene variants (single amino acid substitutions) have been found in ∼30% of a cohort of idiopathic SFN patients, producing gain-of-function changes in sodium channel Na(V)1.7, which is preferentially expressed in small diameter peripheral axons. Functional testing showed that these variants altered fast inactivation, slow inactivation or resurgent current and rendered dorsal root ganglion neurons hyperexcitable. In this review, we discuss the role of Na(V)1.7 in pain and highlight the molecular genetics and pathophysiology of SCN9A-gene variants in SFN. With increasing knowledge regarding the underlying pathophysiology in SFN, the development of specific treatment in these patients seems a logical target for future studies.

Nav1.7-related small fiber neuropathy: impaired slow-inactivation and DRG neuron hyperexcitability.

OBJECTIVES: Although small fiber neuropathy (SFN) often occurs without apparent cause, the molecular etiology of idiopathic SFN (I-SFN) has remained enigmatic. Sodium channel Na(v)1.7 is preferentially expressed within dorsal root ganglion (DRG) and sympathetic ganglion neurons and their small-diameter peripheral axons. We recently reported the presence of Na(v)1.7 variants that produce gain-of-function changes in channel properties in 28% of patients with painful I-SFN and demonstrated impaired slow-inactivation in one of these mutations after expression within HEK293 cells. Here we show that the I739V Na(v)1.7 variant in a patient with biopsy-confirmed I-SFN impairs slow-inactivation within DRG neurons and increases their excitability. METHODS: A patient with SFN symptoms including pain, and no identifiable underlying cause, was evaluated by skin biopsy, quantitative sensory testing, nerve conduction studies, screening of genomic DNA for variants in SCN9A, and functional analysis. RESULTS: Voltage-clamp analysis following expression within DRG neurons revealed that the Na(v)1.7/I739V substitution impairs slow-inactivation, depolarizing the midpoint (V(1/2)) by 5.6 mV, and increasing the noninactivating component at 10 mV from 16.5% to 22.2%. Expression of I739V channels within DRG neurons rendered these cells hyperexcitable, reducing current threshold and increasing the frequency of firing evoked by graded suprathreshold stimuli. CONCLUSIONS: These observations provide support, from a patient with biopsy-confirmed SFN, for the suggestion that functional variants of Na(v)1.7 that impair slow-inactivation can produce DRG neuron hyperexcitability that contributes to pain in SFN. Na(v)1.7 channelopathy-associated SFN should be considered in the differential diagnosis of cases of SFN in which no other cause is found.