Posts tagged cataplexy
Articles and news from the latest research reports.
Scientists shed light on the brain mechanisms behind a debilitating sleep disorder
Researchers at the University of Toronto discover how the body’s muscles accidentally fall asleep while awake
Normally muscles contract in order to support the body, but in a rare condition known as cataplexy the body’s muscles “fall asleep” and become involuntarily paralyzed. Cataplexy is incapacitating because it leaves the affected individual awake, but either fully or partially paralyzed. It is one of the bizarre symptoms of the sleep disorder called narcolepsy.
“Cataplexy is characterized by muscle paralysis during cognitive awareness, but we didn’t understand how this happened until now, said John Peever of the University of Toronto’s Department of Cell & Systems Biology. “We have shown that the neuro-degeneration of the brain cells that synthesize the chemical hypocretin causes the noradrenaline system to malfunction. When the norandrenaline system stops working properly, it fails to keep the motor and cognitive systems coupled. This results in cataplexy – the muscles fall asleep but the brain stays awake.”
Peever and Christian Burgess, also of Cell & Systems Biology used hypocretin-knockout mice (mice that experience cataplexy), to demonstate that a dysfunctional relationship between the noradrenaline system and the hypocretin-producing system is behind cataplexy. The research was recently published in the journal Current Biology.
The scientists first established that mice experienced sudden loss of muscle tone during cataplectic episodes. They then administered drugs to systematically inhibit or activate a particular subset of adrenergic receptors, the targets of noradrenaline. They were able to reduce the incidence of cataplexy by 90 per cent by activating noradrenaline receptors. In contrast, they found that inhibiting the same receptors increased the incidence of cataplexy by 92 per cent. Their next step was to successfully link how these changes affect the brain cells that directly control muscles.
They found that noradrenaline is responsible for keeping the brain cells (motoneurons) and muscles active. But during cataplexy when muscle tone falls, noradrenaline levels disappear. This forces the muscle to relax and causes paralysis during cataplexy. Peever and Burgess found that restoring noradrenaline pre-empted cataplexy, confirming that the noradrenaline system plays a key role.
(Source: media.utoronto.ca)
Researchers find new clue to cause of human narcolepsy
In 2000, researchers at the UCLA Center for Sleep Research published findings showing that people suffering from narcolepsy, a disorder characterized by uncontrollable periods of deep sleep, had 90 percent fewer neurons containing the neuropeptide hypocretin in their brains than healthy people. The study was the first to show a possible biological cause of the disorder.
Subsequent work by this group and others demonstrated that hypocretin is an arousing chemical that keeps us awake and elevates both mood and alertness; the death of hypocretin cells, the researchers said, helps explain the sleepiness of narcolepsy. But it has remained unclear what kills these cells.
Now the same UCLA team reports that an excess of another brain cell type — this one containing histamine — may be the cause of the loss of hypocretin cells in human narcoleptics.
UCLA professor of psychiatry Jerome Siegel and colleagues report in the current online edition of the journal Annals of Neurology that people with the disorder have nearly 65 percent more brain cells containing the chemical histamine. Their research suggests that this excess of histamine cells causes the loss of hypocretin cells in human narcoleptics.
Narcolepsy is a chronic disorder of the central nervous system characterized by the brain’s inability to control sleep–wake cycles. It causes sudden bouts of sleep and is often accompanied by cataplexy, an abrupt loss of voluntary muscle tone that can cause person to collapse. According to the National Institutes of Health, narcolepsy is thought to affect roughly one in every 3,000 Americans. Currently, there is no cure.
Histamine is a body chemical that works as part of the immune system to kill invading cells. When the immune system goes awry, histamine can act on a person’s eyes, nose, throat, lungs, skin or gastrointestinal tract, causing the symptoms of allergy that many people are familiar with. But histamine is also present in a type of brain cell.
For the study, researchers examined five narcoleptic brains and seven control brains from human cadavers. Prior to death, all the narcoleptics had been diagnosed by a sleep disorder center as having narcolepsy with cataplexy. These brains were also compared with the brains of three narcoleptic mouse models and to the brains of narcoleptic dogs.
The researchers found that the humans with narcolepsy had an average of 64 percent more histamine neurons. Interestingly, the team did not see an increased number of these cells in any of the animal models of narcolepsy.
"Humans and animals with narcolepsy share the same symptoms, but we did not see the histamine cell changes we saw in humans in the animal models we examined," said Siegel, who directs the Center for Sleep Research at the UCLA Semel Institute for Neuroscience and Human Behavior and is the senior author of the research. "We know that narcolepsy in the animal models is caused by engineered genetic changes that block hypocretin function. However, in humans, we did not know why the hypocretin cells die.
"Our current findings indicate that the increase of histamine cells that we see in human narcolepsy may cause the loss of hypocretin cells," he said.
The study results may also further our understanding of brain plasticity, Siegel noted. While scientists have known of the existence neurogenesis — the process by which the brain is populated with new neurons — it was thought to function mainly to replace existing cells that had died.
"This paper shows for the first time that neuronal numbers can increase greatly and not just serve as replacement cells," he said. "In the current example, this appears to be pathological with the destruction of hypocretin, but in other circumstances, it may underlie recovery and learning and open new routes to treatment of a number of neurological disorders."