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Sodium Channel Blockers (sodium + channel_blocker)

Distribution by Scientific Domains

Medical Sciences	92%

Distribution within Medical Sciences

Cardiovascular Disease	38%
Pharmacology & Pharmaceutical Medicine	15%
2 Other Subdomains	9%

Selected Abstracts

KC 12291: An Atypical Sodium Channel Blocker with Myocardial Antiischemic Properties

CARDIOVASCULAR THERAPEUTICS, Issue 1 2004
Gareth W. John
ABSTRACT KC 12291 was designed as a voltage-gated sodium channel (VGSC) blocker with cardioprotective properties. KC 12291 has moderate inhibitory effects on peak (or rapid) Na+ current, and markedly reduces sustained (or slowly or non-inactivating) Na+ current. This distinguishes KC 12291 from conventional VGSC blockers such as local anesthetics or antiarrhythmics, which have little or no cardioprotective properties. Since VGSCs represent the main pathway for ischemic Na+ loading by failing to inactivate fully, KC 12291 exerts pronounced antiischemic activity principally by reducing the amplitude of sustained Na+ current. In isolated atria and Langendorff-perfused hearts, KC 12291 inhibits diastolic contracture, renowned for its resistance to pharmacological inhibition, reduces ischemic Na+ loading and preserves cardiac energy status. KC 12291 exerts oral antiischemic activity in vivo in the absence of major hemodynamic effects. Cardiac VGSC blockers such as KC 12291, which block cardiac VGSCs in atypical fashion by effectively inhibiting the sustained component of Na+ current, represent, therefore, promising potential antiischemic and cardioprotective drugs. [source]

Sodium Channel Blockers Enhance the Temporal QT Interval Variability in the Right Precordial Leads in Brugada Syndrome

ANNALS OF NONINVASIVE ELECTROCARDIOLOGY, Issue 1 2008
Tetsuzou Kanemori M.D.
Background: Temporal QT interval variability is associated with sudden cardiac death. The purpose of this study was to evaluate temporal QT interval variability in Brugada syndrome (BS). Methods: We measured QT and RR intervals in precordial leads (V1,V6) based on 12-beat resting ECG recordings from 16 BS patients (B group) with spontaneous ST elevation in right precordial leads (V1,V2) and from 10 patients with normal hearts (C group). We measured the response in B group before and after administration of pilsicainide (1 mg/kg). The standard deviation (QT-SD, RR-SD) of the time domain and total frequency power (QT-TP, RR-TP) were calculated for all precordial leads, and the latter was to analyze the frequency domain. Results: The right precordial leads in BS exhibited an additional and prominent ST elevation (coved-type) after pilsicainide administration. Both QT-SD and QT-TP values were significantly more increased in B, than in C (5.1 ± 1.2 vs 3.6 ± 0.2 and 23.4 ± 2.9 vs 12.3 ± 1.7 msec2, P < 0.01, respectively) and after pilsicainide administration in B. (5.1 ± 0.4 vs 3.9 ± 0.3, 25.8 ± 3.4 vs 16.3 ± 2.6 msec2, P < 0.01, respectively) However, QT-SD and QT-TP did not significantly change in any of other leads (V3,V6) and RR-SD and RR-TP were similar for both groups, as well as after intravenous pilsicainide administration in B. Conclusions: The temporal QT interval variability was identified in BS. Moreover, sodium channel blocker induced temporal fluctuation in QT interval and it may possibly provide a substrate for ventricular arrhythmia in BS patients. [source]

Structurally Minimized ,-Conotoxin Analogues as Sodium Channel Blockers: Implications for Designing Conopeptide-Based Therapeutics

CHEMMEDCHEM, Issue 3 2009
Tiffany
Abstract Transforming the neuroactive toxins of cone snails into small-size compounds poses a challenge due to the presence of multiple disulfide bridges. Herein we describe our successful efforts in minimizing the size of ,-conotoxin while retaining its biological activity. Disulfide bridges that stabilize the native conformation of conotoxins pose a challenge in the synthesis of smaller conotoxin analogues. Herein we describe the synthesis of a minimized analogue of the analgesic ,-conotoxin KIIIA that blocks two sodium channel subtypes, the neuronal NaV1.2 and skeletal muscle NaV1.4. Three disulfide-deficient analogues of KIIIA were initially synthesized in which the native disulfide bridge formed between either C1C9, C2C15, or C4C16 was removed. Deletion of the first bridge only slightly affected the peptide's bioactivity. To further minimize this analogue, the N-terminal residue was removed and two nonessential serine residues were replaced by a single 5-amino-3-oxapentanoic acid residue. The resulting "polytide" analogue retained the ability to block sodium channels and to produce analgesia. Until now, the peptidomimetic approach applied to conotoxins has progressed only modestly at best; thus, the disulfide-deficient analogues containing backbone spacers provide an alternative advance toward the development of conopeptide-based therapeutics. [source]

Clinical picture of EPM1-Unverricht-Lundborg disease

EPILEPSIA, Issue 4 2008
Reetta Kälviäinen
Summary Unverricht-Lundborg disease (ULD), progressive myoclonic epilepsy type 1 (EPM1, OMIM254800), is an autosomal recessively inherited neurodegenerative disorder characterized by age of onset from 6 to 16 years, stimulus-sensitive myoclonus, and tonic,clonic epileptic seizures. Some years after the onset ataxia, incoordination, intentional tremor, and dysarthria develop. Individuals with EPM1 are mentally alert but show emotional lability, depression, and mild decline in intellectual performance over time. The diagnosis of EPM1 can be confirmed by identifying disease-causing mutations in a cysteine protease inhibitor cystatin B (CSTB) gene. Symptomatic pharmacologic and rehabilitative management, including psychosocial support, are the mainstay of EPM1 patients' care. Valproic acid, the first drug of choice, diminishes myoclonus and the frequency of generalized seizures. Clonazepam and high-dose piracetam are used to treat myoclonus, whereas levetiracetam seems to be effective for both myoclonus and generalized seizures. There are a number of agents that aggravate clinical course of EPM1 such as phenytoin aggravating the associated neurologic symptoms or even accelerating cerebellar degeneration. Sodium channel blockers (carbamazepine, oxcarbazepine) and GABAergic drugs (tiagabine, vigabatrin) as well as gabapentin and pregabalin may aggravate myoclonus and myoclonic seizures. EPM1 patients need lifelong clinical follow-up, including evaluation of the drug-treatment and comprehensive rehabilitation. [source]

Selection of Antiepileptic Drug Polytherapy Based on Mechanisms of Action: The Evidence Reviewed

EPILEPSIA, Issue 11 2000
Charles L. P. Deckers
Summary: Purpose: When monotherapy with antiepileptic drugs (AEDs) fails, combination therapy is tried in an attempt to improve effectiveness by improving efficacy, tolerability, or both. We reviewed the available studies (both animal and human) on AED polytherapy to determine whether AEDs can be selected for combination therapy based on their mechanisms of action, and if so, which combinations are associated with increased effectiveness. Because various designs and methods of analysis were used in these studies, it was also necessary to evaluate the appropriateness of these approaches. Methods: Published papers reporting on AED polytherapy in animals or humans were identified by Medline search and by checking references cited in these papers. Results: Thirty-nine papers were identified reporting on two-drug AED combinations. Several combinations were reported to offer improved effectiveness, but no uniform approach was used in either animal or human studies for the evaluation of pharmacodynamic drug interactions; efficacy was often the only end point. Conclusions: There is evidence that AED polytherapy based on mechanisms of action may enhance effectiveness. In particular, combining a sodium channel blocker with a drug enhancing GABAergic inhibition appears to be advantageous. Combining two GABA mimetic drugs or combining an AMPA antagonist with an NMDA antagonist may enhance efficacy, but tolerability is sometimes reduced. Combining two sodium channel blockers seems less promising. However, given the incomplete knowledge of the pathophysiology of seizures and indeed of the exact mechanisms of action of AEDs, an empirical but rational approach for evaluating AED combinations is of fundamental importance. This would involve appropriate testing of all possible combinations in animal models and subsequent evaluation of advantageous combinations in clinical trials. Testing procedures in animals should include the isobologram method, and the concept of drug load should be the basis of studies in patients with epilepsy. [source]

Phentolamine mesylate relaxes rabbit corpus cavernosum by a nonadrenergic, noncholinergic mechanism

FUNDAMENTAL & CLINICAL PHARMACOLOGY, Issue 1 2001
Subbarao Vemulapalli
The contribution of NO-cGMP dependent pathway to phentolamine mesylate-evoked nonadrenergic, noncholinergic relaxation of rabbit corpus cavernosum was investigated in vitro. Stimulation of nonadrenergic, noncholinergic neurons of the rabbit corpus cavernosum elicited frequency-related relaxation that was significantly attenuated by L-NAME (NO synthase inhibitor) or ODQ (an inhibitor of guanylate cyclase). Moreover, tetrodotoxin, a sodium channel blocker, abolished the electrical field stimulation-induced relaxation of rabbit corpus cavernosum, suggesting that neuronal release of NO mediates relaxation to electrical field stimulation. Phentolamine mesylate (30 and 100 nM) dose-dependently enhanced electrical field stimulation-induced relaxation of the rabbit corpus cavernosum. Prazosin (30 ,M) and yohimbine (30 ,M) failed to affect phentolamine mesylate-mediated nonadrenergic, noncholinergic rabbit penile smooth muscle relaxation, suggesting that phentolamine relaxes rabbit corpus cavernosum independent of ,-adrenergic receptor blockade. In contrast, pretreatment of the rabbit cavernosal strips with L-NAME significantly-attenuated electrical field stimulation produced relaxations to phentolamine mesylate, suggesting that phentolamine mesylate relaxes rabbit corpus cavernosum by activating NO synthase. The data suggest that phentolamine mesylate relaxes nonadrenergic noncholinergic neurons of the rabbit corpus cavernosum by activating NO synthase and is independent of ,-adrenergic receptor blockade. [source]

Exacerbation of experimental autoimmune encephalomyelitis after withdrawal of phenytoin and carbamazepine

ANNALS OF NEUROLOGY, Issue 1 2007
Joel A. Black PhD
Objective In vitro observations and studies in murine experimental autoimmune encephalomyelitis (EAE) have shown protective effects of sodium channel blockers on central nervous system axons and improved clinical status when treatment is continued throughout the period of observation. Several clinical studies of sodium channel blockers are under way in patients with multiple sclerosis. Here we asked whether a protective effect would persist after withdrawal of a sodium channel blocker. Methods We studied a mouse model of myelin oligodendrocyte glycoprotein,induced EAE treated with phenytoin or carbamazepine. Results Both phenytoin and carbamazepine significantly improved the clinical course of the disease. Withdrawal of phenytoin resulted in acute exacerbation, accompanied by a significantly increased inflammatory infiltrate within the central nervous system and the death of nearly 60% of EAE mice. There were no clinical worsening or deaths in control mice after withdrawal of phenytoin. Withdrawal of carbamazepine led to acute worsening of EAE symptoms, increased inflammatory infiltrate, and was associated with the death of 8% of mice. Interpretation These results, together with results showing effects of sodium channel blockers in immune cells, raise questions about the long-term effects of sodium channel blockers in neuroinflammatory disorders, and suggest that clinical studies of sodium channel blockers in these disorders should be planned carefully. Ann Neurol 2007 [source]

Sodium Channel Blockers Enhance the Temporal QT Interval Variability in the Right Precordial Leads in Brugada Syndrome

Selection of Antiepileptic Drug Polytherapy Based on Mechanisms of Action: The Evidence Reviewed

Diagnostic Value of Flecainide Testing in Unmasking SCN5A-Related Brugada Syndrome

JOURNAL OF CARDIOVASCULAR ELECTROPHYSIOLOGY, Issue 8 2006
PAOLA G. MEREGALLI M.D.
Introduction: Provocation tests with sodium channel blockers are often required to unmask ECG abnormalities in Brugada syndrome (BrS). However, their diagnostic value is only partially established, while life-threatening ventricular arrhythmias during these tests were reported. We aimed to establish sensitivity, specificity, and safety of flecainide testing, and to predict a positive test outcome from the baseline ECG. Methods and Results: We performed 160 tests with flecainide in subjects determined to be at risk for BrS. P wave width, PQ duration, QRS width, S wave amplitude and duration in leads II-III, in addition to ST morphology and J point elevation in V1-V3 were measured before and after flecainide administration. Moreover, leads were positioned over the third intercostal space (V1IC3 -V2IC3). Flecainide tests were considered positive if criteria from the First Consensus Report on BrS were fulfilled. In 64 cases, the test was positive, while 95 were negative (1 test was prematurely interrupted). The sensitivity and specificity, calculated in SCN5A-positive probands and their family members, were 77% and 80%, respectively. Baseline ECGs exhibited significant group differences in P, PQ, and QRS duration, J point elevation (leads V1-V2 and V1IC3 -V2IC3), and S duration in II, but an attempt to predict the outcome of flecainide testing from these baseline ECG parameters failed. No malignant arrhythmias were observed. Conclusion: Flecainide testing is a valid and safe tool to identify SCN5A-related BrS patients. Baseline ECGs do not predict test outcomes, but point to conduction slowing as a core mechanism in BrS. [source]

Electrophysiological Basis and Genetics of Brugada Syndrome

JOURNAL OF CARDIOVASCULAR ELECTROPHYSIOLOGY, Issue 2005
AUGUSTUS O. GRANT M.B.Ch.B., Ph.D.
Brugada syndrome is a primary arrhythmic syndrome arising in the structurally normal heart. Any proposed mechanism should account for the major features of the syndrome: localization of the ST segment and T-wave changes to the right precordial leads, association of conduction slowing at several levels, precipitation or aggravation of the major ECG changes by sodium channel-blocking drugs and the occurrence of ventricular fibrillation. Heterogeneity of repolarization across the ventricle wall plays a major role. Any agency that shifts the net current gradient during phase I outward would exaggerate the normal heterogeneity of repolarization and result in the ST segment and T-wave changes characteristic of the syndrome. When the outward current shift is marked, premature repolarization may occur in epicardial zone and the resulting gradient may precipitate reentry. The syndrome is inherited as an autosomal dominant. However, 75% of clinically affected individuals are males. In 20% of cases, the syndrome is associated with mutations of the cardiac sodium channel gene SCN5A. The mutations result in a loss-of-function as a result of the synthesis of a non-functional protein, altered protein trafficking, or change in gating. Agencies that reduce the sodium current may precipitate the characteristic ECG changes, for example, sodium channel blockers and membrane depolarization by hyperkalemia. Sympathetic stimulation may reverse the ECG changes and reduce arrhythmia recurrence. By its nonspecific potassium channel blocking action, quinidine may also reduce arrhythmia recurrence. We still do not know the basis for defect in the majority of patients with Brugada syndrome. [source]

Voltage-Gated Sodium Channels: Therapeutic Targets for Pain

PAIN MEDICINE, Issue 7 2009
Sulayman D. Dib-Hajj PhD
ABSTRACT Objective., To provide an overview of the role of voltage-gated sodium channels in pathophysiology of acquired and inherited pain states, and of recent developments that validate these channels as therapeutic targets for treating chronic pain. Background., Neuropathic and inflammatory pain conditions are major medical needs worldwide with only partial or low efficacy treatment options currently available. An important role of voltage-gated sodium channels in many different pain states has been established in animal models and, empirically, in humans, where sodium channel blockers partially ameliorate pain. Animal studies have causally linked changes in sodium channel expression and modulation that alter channel gating properties or current density in nociceptor neurons to different pain states. Biophysical and pharmacological studies have identified the sodium channel isoforms Nav1.3, Nav1.7, Nav1.8, and Nav1.9 as particularly important in the pathophysiology of different pain syndromes. Recently, gain-of-function mutations in SCN9A, the gene which encodes Nav1.7, have been linked to two human-inherited pain syndromes, inherited erythromelalgia and paroxysmal extreme pain disorder, while loss-of-function mutations in SCN9A have been linked to complete insensitivity to pain. Studies on firing properties of sensory neurons of dorsal root ganglia demonstrate that the effects of gain-of-function mutations in Nav1.7 on the excitability of these neurons depend on the presence of Nav1.8, which suggests a similar physiological interaction of these two channels in humans carrying the Nav1.7 pain mutation. Conclusions., These studies suggest that isoform-specific blockers of these channels or targeting of their modulators may provide novel approaches to treatment of pain. [source]

Exacerbation of experimental autoimmune encephalomyelitis after withdrawal of phenytoin and carbamazepine

Investigation Of AM-36: A Novel Neuroprotective Agent

CLINICAL AND EXPERIMENTAL PHARMACOLOGY AND PHYSIOLOGY, Issue 11 2001
Jk Callaway
SUMMARY 1. The neurochemical sequelae following cerebral ischaemia are complex, involving excess release of excitatory amino acids, particularly glutamate, disruption of ionic homeostasis due to Na+ and Ca2+ influx and generation of toxic free radicals, ultimately leading to cell death by both necrosis and apoptosis. 2. Drugs that block components of this biochemical cascade, such as glutamate receptor antagonists, sodium channel blockers and free radical scavengers, have been investigated as putative neuroprotective agents. The knowledge that multiple mechanisms contribute to neuronal injury in ischaemia have led to the general recognition that a single drug treatment is unlikely to be beneficial in the treatment of cerebral ischaemia. 3. AM-36 [1-(2-(4-chlorophenyl)-2-hydroxy)ethyl-4-(3,5-bis(1,1-dimethyl)-4-hydroxyphenyl)methylpiperazine] is one of a series of hybrid molecules designed to incorporate multiple neuroprotective mechanisms within the one structure. Primary screening tests demonstrated that AM-36 inhibited binding to the polyamine site of glutamate receptors, blocked neuronal sodium channels and had potent anti-oxidant activity. In neuronal cell cultures, AM-36 inhibited toxicity induced by N -methyl- D -aspartate (NMDA) and the sodium channel opener veratridine and, in addition, inhibited veratridine-induced apoptosis. 4. In a middle cerebral artery occlusion model of stroke in conscious rats, systemic administration of AM-36 markedly reduced both cortical and striatal infarct volume and significantly improved functional outcome in motor performance, neurological deficit and sensorimotor neglect tests. AM-36 was neuroprotective even when administration was delayed until 3 h systemically, or 5 h intravenously, after induction of stroke. 5. These studies indicate that AM-36 is a unique neuroprotective agent with multiple modes of action, making it an attractive candidate for the treatment of acute stroke in humans. [source]