Book contents
- Medication-Resistant Epilepsy
- Medication-Resistant Epilepsy
- Copyright page
- Dedication
- Contents
- Contributors
- Chapter 1 The Natural History of Epilepsy
- Chapter 2 Challenges in Identifying Medication-Resistant Epilepsy
- Chapter 3 International League Against Epilepsy’s Definition of Medication-Resistant Epilepsy
- Chapter 4 The Economic Impact of Medication-Resistant Epilepsy
- Chapter 5 Social Consequences of Medication-Resistant Epilepsy
- Chapter 6 Mortality and Morbidity of Medication-Resistant Epilepsy
- Chapter 7 Models for Medication-Resistant Epilepsy
- Chapter 8 Neurobiology of Medication-Resistant Epilepsy
- Chapter 9 Genetic Causes of Medication-Resistant Epilepsy
- Chapter 10 Malformations of Cortical Development as Causes of Medication-Resistant Epilepsy
- Chapter 11 Hippocampal Sclerosis as a Cause of Medication-Resistant Epilepsy
- Chapter 12 Autoimmune Causes of Medication-Resistant Epilepsy
- Chapter 13 Medication-Resistant Epilepsy Syndromes in Children
- Chapter 14 Medication-Resistant Epilepsy in Adults
- Chapter 15 Approach to the Treatment of Medication-Resistant Epilepsy
- Chapter 16 Pharmacotherapy for Medication-Resistant Epilepsy
- Chapter 17 Reproductive Health for Women with Medication-Resistant Epilepsy
- Chapter 18 Resective Surgery for Medication-Resistant Epilepsy
- Chapter 19 Ablative Surgery for Medication-Resistant Epilepsy
- Chapter 20 Stimulation Treatment for Medication-Resistant Epilepsy
- Chapter 21 Diet Therapy for Medication-Resistant Epilepsy
- Chapter 22 Botanical Treatments for Medication-Resistant Epilepsy
- Chapter 23 Psychiatric Comorbidities in Medication-Resistant Epilepsy
- Index
- References
Chapter 7 - Models for Medication-Resistant Epilepsy
Published online by Cambridge University Press: 20 August 2020
By
Book contents
- Medication-Resistant Epilepsy
- Medication-Resistant Epilepsy
- Copyright page
- Dedication
- Contents
- Contributors
- Chapter 1 The Natural History of Epilepsy
- Chapter 2 Challenges in Identifying Medication-Resistant Epilepsy
- Chapter 3 International League Against Epilepsy’s Definition of Medication-Resistant Epilepsy
- Chapter 4 The Economic Impact of Medication-Resistant Epilepsy
- Chapter 5 Social Consequences of Medication-Resistant Epilepsy
- Chapter 6 Mortality and Morbidity of Medication-Resistant Epilepsy
- Chapter 7 Models for Medication-Resistant Epilepsy
- Chapter 8 Neurobiology of Medication-Resistant Epilepsy
- Chapter 9 Genetic Causes of Medication-Resistant Epilepsy
- Chapter 10 Malformations of Cortical Development as Causes of Medication-Resistant Epilepsy
- Chapter 11 Hippocampal Sclerosis as a Cause of Medication-Resistant Epilepsy
- Chapter 12 Autoimmune Causes of Medication-Resistant Epilepsy
- Chapter 13 Medication-Resistant Epilepsy Syndromes in Children
- Chapter 14 Medication-Resistant Epilepsy in Adults
- Chapter 15 Approach to the Treatment of Medication-Resistant Epilepsy
- Chapter 16 Pharmacotherapy for Medication-Resistant Epilepsy
- Chapter 17 Reproductive Health for Women with Medication-Resistant Epilepsy
- Chapter 18 Resective Surgery for Medication-Resistant Epilepsy
- Chapter 19 Ablative Surgery for Medication-Resistant Epilepsy
- Chapter 20 Stimulation Treatment for Medication-Resistant Epilepsy
- Chapter 21 Diet Therapy for Medication-Resistant Epilepsy
- Chapter 22 Botanical Treatments for Medication-Resistant Epilepsy
- Chapter 23 Psychiatric Comorbidities in Medication-Resistant Epilepsy
- Index
- References
Summary
The earliest effective therapies for the treatment of epilepsy emerged in the nineteenth and early twentieth centuries without the use of any model systems. As documented engrossingly by Professor Martin Brodie [1], the description of the utility of bromides in the treatment of ‘hysterical’ epilepsy in young women by Sir Charles Locock in 1857, and the serendipitous discovery of the anti-convulsant properties of phenobarbital by Alfred Hauptman in 1912 [2] stemmed directly from human observations. It was Tracy Putnam who first set up a laboratory with electroencephalographic (EEG) equipment and studied the ability of compounds to protect cats from electroconvulsive seizures. The compounds were related to phenobarbital, and represented a portfolio of molecules developed by Parke, Davis & Company to create non-sedative anti-seizure drugs. Using the feline electroshock model (maximal electroshock seizures, MES), Putnam identified phenytoin (PHT) as a suitable candidate for clinical evaluation. Houston Merritt, his assistant, successfully used it to treat seizures in patients who were refractory to available treatments at that time [3].
- Type
- Chapter
- Information
- Medication-Resistant EpilepsyDiagnosis and Treatment, pp. 51 - 61Publisher: Cambridge University PressPrint publication year: 2020
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