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Shiromani, Priyattam

One or more keywords matched the following properties of Shiromani, Priyattam

Property	Value
overview	Sleep Molecular Laboratory The lab’s research strategy is to identify the neural circuitry responsible for the alternation between wake, sleep and REM sleep. Sleep and circadian rhythms of body temperature and activity are measured in rodents (rats and mice). Molecular (Dr. Meng Liu), pharmacological (Dr. Carlos Blanco-Centurion), anatomical (Dr. RodaRani Konadhode) and electrophysiology (Dr. Dheeraj Pelluru) methods are used to trace the network, record activity of neurons, identify gene expression in specific neuronal populations and whether destruction of specific neurons or loss of specific genes affects sleep. To destroy orexin receptor bearing neurons we created a novel compound linking saporin to the ligand orexin. This compound provides a rapid, cost effective method to test specific hypotheses regarding the role of specific brain regions in sleep-wake regulation. Once it is found that loss of a gene or neurons results in a sleep abnormality then novel methods are used to repair the network and determine whether sleep returns to normal. Recently, we demonstrated the first ever use of gene transfer to treat a sleep disorder. Our most recent study identified an hitherto unknown group of neurons in the subthalamus that control cataplexy, an important symptom of narcolepsy (Liu et al., J Neuroscience, 2011). The primary focus of the research is on the sleep disorder, narcolepsy. Dr. Shiromani’s research career was started in 1986 by a small grant from the American Narcolepsy Association. Since then the laboratory has been continuously funded by the NIH, the VA and the DoD. This lab provides training in long-term (months) recording of sleep and circadian rhythms in rodents. Dr. Shiromani has trained many students who have now established their own labs. Training is also provided in molecular biology, immunohistochemistry, microdialysis, HPLC and single cell recording of neurons in freely-behaving rodents.

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overview

Sleep Molecular Laboratory The lab’s research strategy is to identify the neural circuitry responsible for the alternation between wake, sleep and REM sleep. Sleep and circadian rhythms of body temperature and activity are measured in rodents (rats and mice). Molecular (Dr. Meng Liu), pharmacological (Dr. Carlos Blanco-Centurion), anatomical (Dr. RodaRani Konadhode) and electrophysiology (Dr. Dheeraj Pelluru) methods are used to trace the network, record activity of neurons, identify gene expression in specific neuronal populations and whether destruction of specific neurons or loss of specific genes affects sleep. To destroy orexin receptor bearing neurons we created a novel compound linking saporin to the ligand orexin. This compound provides a rapid, cost effective method to test specific hypotheses regarding the role of specific brain regions in sleep-wake regulation. Once it is found that loss of a gene or neurons results in a sleep abnormality then novel methods are used to repair the network and determine whether sleep returns to normal. Recently, we demonstrated the first ever use of gene transfer to treat a sleep disorder. Our most recent study identified an hitherto unknown group of neurons in the subthalamus that control cataplexy, an important symptom of narcolepsy (Liu et al., J Neuroscience, 2011). The primary focus of the research is on the sleep disorder, narcolepsy. Dr. Shiromani’s research career was started in 1986 by a small grant from the American Narcolepsy Association. Since then the laboratory has been continuously funded by the NIH, the VA and the DoD. This lab provides training in long-term (months) recording of sleep and circadian rhythms in rodents. Dr. Shiromani has trained many students who have now established their own labs. Training is also provided in molecular biology, immunohistochemistry, microdialysis, HPLC and single cell recording of neurons in freely-behaving rodents.

One or more keywords matched the following items that are connected to Shiromani, Priyattam

Item Type	Name
Academic Article	Relationship between CSF hypocretin levels and hypocretin neuronal loss.
Academic Article	Hypocretin-2-saporin lesions of the lateral hypothalamus produce narcoleptic-like sleep behavior in the rat.
Academic Article	Effects of orexin gene transfer in the dorsolateral pons in orexin knockout mice.
Academic Article	Effects of lateral hypothalamic lesion with the neurotoxin hypocretin-2-saporin on sleep in Long-Evans rats.
Academic Article	Acetylcholine and the regulation of REM sleep: basic mechanisms and clinical implications for affective illness and narcolepsy.
Academic Article	Neuronal activity in narcolepsy: identification of cataplexy-related cells in the medial medulla.
Academic Article	The development of hypocretin (orexin) deficiency in hypocretin/ataxin-3 transgenic rats.
Academic Article	Orexin (hypocretin) gene transfer diminishes narcoleptic sleep behavior in mice.
Academic Article	Orexin gene transfer into zona incerta neurons suppresses muscle paralysis in narcoleptic mice.
Concept	Narcolepsy
Academic Article	Rewiring brain circuits to block cataplexy in murine models of narcolepsy.

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Narcolepsy