Your search keyword '"Tomlinson SE"' showing total 3 results

1. In vivo assessment of neurological channelopathies: Application of peripheral nerve excitability studies.

Author

Tomlinson SE, Howells J, and Burke D

Subjects

Animals, Channelopathies diagnosis, Humans, Channelopathies physiopathology, Peripheral Nerves physiopathology

Abstract

With the rapid evolution of understanding of neurological channelopathies comes a need for sensitive tools to evaluate patients in clinical practice. Neurological channelopathies with a single-gene basis can manifest as seizures, headache, ataxia, vertigo, confusion, weakness and neuropathic pain and it is likely that other genetic factors contribute to the phenotype of many of these disorders. Ion channel dysfunction can result in abnormal cell membrane excitability but utilisation of advanced neurophysiology techniques has lagged behind developments in clinical, genetic and imaging evaluation of channelopathies. However, momentum in the application of in vivo axonal excitability testing sees these tests emerging as valuable tools, with the capacity to provide sensitive and specific insights into the mechanism of disease. While single-channel function cannot be directly measured in vivo, evaluation of subjects with single-gene channelopathies has provided insights into the effects of mutation-related alterations of membrane excitability, as well as compensatory adaptive changes. By showing how ion channel dysfunction can affect axonal excitability in vivo, studies of the excitability of peripheral nerve axons complement in vitro analysis of single channel activity. The interpretation of results is enhanced by mathematical modelling of axonal function and insights provided by in vitro work. This article is part of the Special Issue entitled 'Channelopathies.', (Copyright © 2017. Published by Elsevier Ltd.)

Published

2018

2. In vivo loss of slow potassium channel activity in individuals with benign familial neonatal epilepsy in remission.

Author

Tomlinson SE, Bostock H, Grinton B, Hanna MG, Kullmann DM, Kiernan MC, Scheffer IE, Berkovic SF, and Burke D

Subjects

Adult, Axons pathology, Axons physiology, Channelopathies physiopathology, Cohort Studies, Epilepsy, Benign Neonatal physiopathology, Female, Humans, KCNQ2 Potassium Channel metabolism, Male, Middle Aged, Mutation genetics, Secondary Prevention, Channelopathies genetics, Channelopathies metabolism, Epilepsy, Benign Neonatal genetics, Epilepsy, Benign Neonatal metabolism, KCNQ2 Potassium Channel antagonists & inhibitors, KCNQ2 Potassium Channel genetics

Abstract

Benign familial neonatal epilepsy is a neuronal channelopathy most commonly caused by mutations in KCNQ2, which encodes the K(v)7.2 subunit of the slow K(+) channel. K(v)7.2 is expressed in both central and peripheral nervous systems. Seizures occur in the neonatal period, often in clusters within the first few days of life, and usually remit by 12 months of age. The mechanism of involvement of K(v)7.2 mutations in the process of seizure generation has not been established in vivo. In peripheral axons, K(v)7.2 contributes to the nodal slow K(+) current. The present study aimed to determine whether axonal excitability studies could detect changes in peripheral nerve function related to dysfunction or loss of slow potassium channel activity. Nerve excitability studies were performed on eight adults with KCNQ2 mutations and a history of benign familial neonatal epilepsy, now in remission. Studies detected distinctive changes in peripheral nerve, indicating a reduction in slow K(+) current. Specifically, accommodation to long-lasting depolarizing currents was reduced in mutation carriers by 24% compared with normal controls, and the threshold undershoot after 100 ms depolarizing currents was reduced by 22%. Additional changes in excitability included a reduction in the relative refractory period, an increase in superexcitability and a tendency towards reduced sub-excitability. Modelling of the nerve excitability changes suggested that peripheral nerve hyperexcitability may have been ameliorated by upregulation of other potassium channels. We conclude that subclinical dysfunction of K(v)7.2 in peripheral axons can be reliably detected non-invasively in adulthood. Related alterations in neuronal excitability may contribute to epilepsy associated with KCNQ2 mutations.

Published

2012

3. Clinical neurophysiology of the episodic ataxias: insights into ion channel dysfunction in vivo.

Author

Tomlinson SE, Hanna MG, Kullmann DM, Tan SV, and Burke D

Subjects

Animals, Electrophysiology, Humans, Ataxia genetics, Ataxia physiopathology, Calcium Channels, L-Type physiology, Channelopathies genetics, Channelopathies physiopathology, Potassium Channels, Voltage-Gated physiology

Abstract

Clinical neurophysiology has become an invaluable tool in the diagnosis of muscle channelopathies, but the situation is less clear cut with neuronal channelopathies. The genetic episodic ataxias are a group of disorders with heterogeneous phenotype and genotype, but share in common the feature of intermittent cerebellar dysfunction. Episodic ataxia (EA) types 1 and 2 are the most widely recognised of the autosomal dominant episodic ataxias and are caused by dysfunction of neuronal voltage-gated ion channels. There are central and peripheral nervous system manifestations in both conditions, and they are therefore good models of neuronal channelopathies to study neurophysiologically. To date most work has focussed upon characterising the electrophysiological properties of mutant channels in vitro. This review summarises the role of voltage-gated potassium and calcium channels, mutations of which underlie the main types of episodic ataxia types 1 and 2. The clinical, genetic and electrophysiological features of EA1 and EA2 are outlined, and a protocol for the assessment of these patients is proposed.

Published

2009