Temporal and Spatial Profiles of Pontine-Evoked Monoamine Release in the Rat's Spinal Cord

doi:10.1152/jn.00608.2002

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Temporal and Spatial Profiles of Pontine-Evoked Monoamine Release in the Rat's Spinal Cord

Ian D. Hentall², Riza Mesigil¹, Alberto Pinzon¹^,3 and Brian R. Noga¹

¹The Miami Project to Cure Paralysis, University of Miami School of Medicine, Miami, Florida 33101; ²Department of Biomedical Sciences, University of Illinois College of Medicine, Rockford, Illinois 61107-1897; and ³Department of Biomedical Engineering, University of Miami, Miami, Florida 33124

Submitted 26 July 2002; accepted in final form 3 February 2003

In the spinal cord, the monoamine neurotransmitter norepinephrine,which is released mainly from fibers descending from the dorsalpons, has major modulatory effects on nociception and locomotorrhythms. To map the spatial and temporal patterns of this release,changes in monoamine level were examined in laminae I–VIIIof lumbar segments L₃–L₆ of halothane-anesthetized ratsduring pontine stimulation. The changes were measured througha carbon fiber microelectrode at 0.5-s intervals by fast cyclicvoltammetry, which presently is the method of best spatiotemporalresolution. When different pontine sites were tested with 20-spulse trains (50-to 200-µA amplitude, 0.5-ms pulse width,and 50-Hz frequency) during measurement in the dorsal horn (laminaIV), the largest consistent increases were produced by thelocus ceruleus, although effective pontine sites extended 1.5mm dorsally and ventral from the locus ceruleus. When the locusceruleus stimulus was used to map the spinal cord, increasedlevels were always seen in lamina I and laminae IV–VIII, whereas 50% of sites in laminae II and III showed substantialdecreases and the rest showed increases. These increases typicallyhad short latencies [4.5 ± 0.4 (SE) s] and variabledecay times (5–200 s), with peaks occurring during thestimulus train (mean rise-time: 12.0 ± 0.6 s). The meanpeak level was 544 ± 82 nM as estimated from postexperimental calibration with norepinephrine. Other significant laminardifferences included higher mean peak concentrations (805 nM)and rise times (14.9 s) in lamina I and shorter latencies inlamina VI (3.2 s). Peak concentrations were inversely correlatedwith latency. When stimulation frequency was varied, increaseswere disproportionately larger with faster frequencies ( $>=$ 50 Hz), hence extrajunctional overflow probably contributed most ofthe signal. We conclude, generally, that pontine noradrenergiccontrol is exerted on widespread spinal laminae with a significantcomponent of paracrine transmission after several seconds ofsustained activity. Relatively stronger effects prevail wherenociceptive transmission (lamina I) and locomotor rhythm generation(lamina VI) occur.

Address for reprint requests: Dr. Brian Noga, The Miami Project to Cure Paralysis, University of Miami School of Medicine, P.O. Box 016960, R-48, Miami, Florida 33101 (E-mail: bnoga{at}miamiproj.med.miami.edu).

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