Skip to content

J Heym

3 papers in the library · 171 citations · publishing 1982-1984

Papers

Activity of serotonin-containing neurons in nucleus centralis superior of freely moving cats.

Experimental neurology February 1, 1984 K Rasmussen, J Heym, B L Jacobs 125 citations

Serotonergic neurons in the nucleus centralis superior (NCS) of freely moving cats fire most rapidly during active waking (mean 2.94 spikes/s), slow down during slow-wave sleep (mean 1.38 spikes/s), and are least active during REM sleep (mean 0.46 spikes/s). Their activity does not increase with transient muscle movements but decreases just before and during sleep spindles. Most NCS serotonergic neurons are excited by sudden sounds or lights. A serotonin-like drug reduces their firing by about 44%. A subset of these neurons shows much smaller changes across sleep-wake states and is inhibited, rather than excited, by sensory stimuli. These patterns are compared with serotonergic neurons in other brain regions.

Raphe neurons: firing rate correlates with size of drug response.

European journal of pharmacology June 3, 1983 B L Jacobs, J Heym, K Rasmussen 25 citations

In unanesthetized and unrestrained cats, serotonergic neurons in several raphe nuclei showed a strong negative correlation between their spontaneous firing rate during waking and their response to systemic injections of the serotonin agonists 5-MeODMT or LSD. The authors propose that both the baseline activity of these neurons and the size of their response to serotonin-like drugs can be explained by the density of autoreceptors on each neuron.

Medullary serotonergic neurons are insensitive to 5-MeoDMT and LSD.

European journal of pharmacology July 30, 1982 J Heym, G F Steinfels, B L Jacobs 21 citations

In freely moving cats, neurons in the dorsal raphe nucleus (DRN) are much more sensitive to the psychedelic compounds 5-MeO-DMT and LSD than neurons in the nucleus raphe pallidus (NRP). Low, behaviorally effective doses of these drugs strongly suppress activity in DRN neurons, while NRP neurons remain largely unaffected. This differential sensitivity suggests a unique autoregulatory control mechanism within distinct brain regions, where serotonin-producing neurons respond differently depending on their neuroanatomical location.