Different flecainide sensitivity of hNa<sub>v</sub>1.4 channels and myotonic mutants explained by state‐dependent block

Desaphy, Jean-François; Luca, Annamaria De; Didonna, Maria Paola; George, Alfred L.; Camerino, Diana Conte

doi:10.1113/jphysiol.2003.046995

Cited by 44 publications

(64 citation statements)

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“…In fact, even though flecainide and mexiletine exhibit a similar mechanism of blocking skeletal muscle sodium channels, flecainide reportedly inhibits some mutant channels more efficiently than mexiletine. 14,15 Although flecainide has been shown to be an effective human voltage-gated sodium channel blocker in vitro, its clinical use as an antimyotonic agent has rarely been reported. 8,22 Indeed, it has been shown previously that flecainide was more efficient than mexiletine in blocking functionally expressed G1306E channels, likely because of a positive shift of channel availability voltage dependence induced by the mutation.…”

Section: Figurementioning

confidence: 99%

“…8,22 Indeed, it has been shown previously that flecainide was more efficient than mexiletine in blocking functionally expressed G1306E channels, likely because of a positive shift of channel availability voltage dependence induced by the mutation. 14 …”

Section: Figurementioning

confidence: 99%

“…Since early childhood, he had been treated with mexiletine, with limited effects. Having already demonstrated the in vitro beneficial effects of flecainide on that specific mutation, 14 the authors decided to administer, for the first time, flecainide in mother and son, and a marked improvement in symptoms was noted. 13 In 2013, Caietta et al 15 reported on 2 other SNEL patients with a p.G1306E de novo mutation.…”

Section: Figurementioning

confidence: 99%

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Flecainide-Responsive Myotonia Permanens With SNEL Onset: A New Case and Literature Review

et al. 2016

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Sodium channel myotonias are inherited muscle diseases linked to mutations in the voltage-gated sodium channel. These diseases may also affect newborns with variable symptoms. More recently, severe neonatal episodic laryngospasm (SNEL) has been described in a small number of patients. A timely diagnosis of SNEL is crucial because a specific treatment is now available that will likely reduced laryngospasm and improve vital and cerebral outcomes. We report here on an 8-year-old girl who had presented, at birth, with SNEL who subsequently developed myotonia permanens starting at age 3 years. Results of molecular analysis revealed a de novo SCN4A G1306E mutation. The girl was treated with carbamazepine, acetazolamide, and mexiletine, with little improvement; after switching her treatment to flecainide, she experienced a dramatic reduction in muscle stiffness and myotonic symptoms as well as an improvement in behavior.

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Section: Figurementioning

confidence: 99%

Section: Figurementioning

confidence: 99%

Section: Figurementioning

confidence: 99%

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Flecainide-Responsive Myotonia Permanens With SNEL Onset: A New Case and Literature Review

et al. 2016

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“…The reduction in the rate of I Na decay 26,27 and the enhanced rate of recovery from inactivation 7,8 exhibited by R1448 mutant channels are features which may increase excitability and contribute to myotonia.…”

confidence: 99%

Ranolazine block of human Na_v1.4 sodium channels and paramyotonia congenita mutants

El-Bizri¹,

Kahlig²,

Shyrock³

et al. 2011

Channels

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“…A more potent Na V Ch blocker, flecainide, may also have utility in severe forms of myotonia that are resistant to mexiletine (55). The efficacy of flecainide for treating myotonia associated with certain SCN4A mutations may be greatest when there is a depolarizing shift of the steady-state fast inactivation curve for the mutant channel, whereas mutations that induce hyperpolarizing shifts in this curve are predicted to have greater sensitivity to mexiletine (56). Longterm treatment of myotonia with Na V Ch blockers is often limited by drug side effects.…”

Section: Muscle Sodium Channelopathiesmentioning

confidence: 99%

Inherited disorders of voltage-gated sodium channels

George

2005

Journal of Clinical Investigation

333

267

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A variety of inherited human disorders affecting skeletal muscle contraction, heart rhythm, and nervous system function have been traced to mutations in genes encoding voltage-gated sodium channels. Clinical severity among these conditions ranges from mild or even latent disease to life-threatening or incapacitating conditions. The sodium channelopathies were among the first recognized ion channel diseases and continue to attract widespread clinical and scientific interest. An expanding knowledge base has substantially advanced our understanding of structurefunction and genotype-phenotype relationships for voltage-gated sodium channels and provided new insights into the pathophysiological basis for common diseases such as cardiac arrhythmias and epilepsy. IntroductionVoltage-gated sodium channels (Na V Chs) are important for the generation and propagation of signals in electrically excitable tissues like muscle, the heart, and nerve. Activation of Na V Chs in these tissues causes the initial upstroke of the compound action potential, which in turn triggers other physiological events leading to muscular contraction and neuronal firing. Na V Chs are also important targets for local anesthetics, anticonvulsants, and antiarrhythmic agents.The essential nature of Na V Chs is emphasized by the existence of inherited disorders (sodium "channelopathies") caused by mutations in genes that encode these vital proteins. Nearly 20 disorders affecting skeletal muscle contraction, cardiac rhythm, or neuronal function and ranging in severity from mild or latent disease to life-threatening or incapacitating conditions have been linked to mutations in human Na V Ch genes (Table 1). Most sodium channelopathies are dominantly inherited, but some are transmitted by recessive inheritance or appear sporadic. Additionally, certain pharmacogenetic syndromes have been traced to variants in Na V Ch genes. The clinical manifestations of these disorders depend primarily on the expression pattern of the mutant gene at the tissue level and the biophysical character of Na V Ch dysfunction at the molecular level.This review will cover the current state of knowledge of human sodium channelopathies and illustrate important links among clinical, genetic, and pathophysiological features of the major syndromes with the corresponding biophysical properties of mutant Na V Chs. An initial brief overview of the structure and function of Na V Chs will provide essential background information needed to understand the nuances of these relationships. This will be followed by a review of the major syndromes, organized by affected tissue. Emphasis will be placed on relating clinical phenotypes to patterns of channel dysfunction that underlie pathophysiology of these conditions.

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Different flecainide sensitivity of hNa_v1.4 channels and myotonic mutants explained by state‐dependent block

Cited by 44 publications

References 44 publications

Flecainide-Responsive Myotonia Permanens With SNEL Onset: A New Case and Literature Review

Flecainide-Responsive Myotonia Permanens With SNEL Onset: A New Case and Literature Review

Ranolazine block of human Na_v1.4 sodium channels and paramyotonia congenita mutants

Inherited disorders of voltage-gated sodium channels

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Different flecainide sensitivity of hNav1.4 channels and myotonic mutants explained by state‐dependent block

Cited by 44 publications

References 44 publications

Flecainide-Responsive Myotonia Permanens With SNEL Onset: A New Case and Literature Review

Flecainide-Responsive Myotonia Permanens With SNEL Onset: A New Case and Literature Review

Ranolazine block of human Nav1.4 sodium channels and paramyotonia congenita mutants

Inherited disorders of voltage-gated sodium channels

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Different flecainide sensitivity of hNa_v1.4 channels and myotonic mutants explained by state‐dependent block

Ranolazine block of human Na_v1.4 sodium channels and paramyotonia congenita mutants