RT Journal Article SR Electronic T1 Cataplexy JF Practical Neurology JO Pract Neurol FD BMJ Publishing Group Ltd SP 21 OP 27 DO 10.1136/practneurol-2018-002001 VO 19 IS 1 A1 Reading, Paul YR 2019 UL http://pn.bmj.com/content/19/1/21.abstract AB Remarkably and almost invariably, the clinical phenomenon of cataplexy results from the loss of around 40 000 hypocretin-containing neurones in the lateral hypothalamus in the context of narcolepsy type 1. Cataplexy reflects the dysregulation of rapid-eye-movement (REM) sleep, such that REM-sleep atonia intrudes inappropriately into wakefulness as brief episodes of either focal or total paralysis of voluntary muscle. The semiology of cataplexy differs between adults and children. A defining and enigmatic aspect is that certain emotional stimuli usually trigger the episodes. Cataplexy can be the most disabling symptom of the narcolepsy syndrome, severely limiting normal activities of daily living. Antidepressant drug therapy at relatively low doses is the traditional treatment; these most likely work through inhibiting REM sleep, predominantly by increasing brain monoamine concentrations. Sodium oxybate is probably the most effective drug for severe cataplexy, taken before overnight sleep and once through the night; its precise mechanism of action remains obscure. Pitolisant is a new agent for treating the excessive daytime sleepiness of narcolepsy that also helps cataplexy control by increasing histamine concentrations in the hypothalamus. Further understanding of the neurobiology of cataplexy and how it relates to hypocretin deficiency should improve our understanding of the brain’s emotional processing and provide insights into REM sleep and its control.