Turnover and synthesis of biogenic amines in discrete brainstem nuclei of the rabbit

Immunocytochemical detection of serotonin content in raphe neurons of newborn and young adult rabbits before and after acute hypoxia

The present immunocytochemical study demonstrates serotonin (5-HT) depletion in the dorsal raphe nucleus (DRN) of 3- and 21-day-old rabbits following exposure to mild (10% ambient partial pressure of oxygen) and severe hypoxia (5% ambient oxygen). Under the mild hypoxic condition, 5-HT immunoreactivity in cells and fibers of the DRN was decreased in 3-day-old as well as 21-day-old rabbits, as indicated by decreased intensity of the staining compared to age-matched controls. Although this decrease was more pronounced in the younger animals, recovery from mild hypoxia was seen in both age groups. Hypoxic effects were more striking in 3-day-old animals under the severe hypoxic condition, indicating a greater depletion of 5-HT than in the mildly hypoxic condition. However, little additional effect on the older age group was seen. Further, a decreased ability of the 3-day-old rabbits to recover following severe hypoxia suggests that protracted effects on the developing serotonergic system occur following severe hypoxia during the neonatal period. This was demonstrated by the long-lasting decrease in the number of stained cells and fibers of the DRN 4-hr after return to normal conditions (21% O2). We conclude that newborns have a decreased rate of 5-HT synthesis and/or metabolic turnover that results in rapid depletion of intracellular stores and protracted time to recover from a hypoxic challenge. Similar effects could occur in human fetuses, newborns or infants following birth trauma, apnea or other events associated with severe hypoxia.

Endogenous serotonin modulates the fetal respiratory rhythm: an in vitro study in the rat

The aim of the present work was to know whether the excitatory modulation of the central respiratory rhythm generator by serotonin (5-HT) previously found to occur in the newborn rat, is already functional during the fetal life. Experiments were performed at embryonic day 18 (D18) and 20-21 (D20-21; full-term day 21) on the fetal rat brainstem-spinal cord preparation in which the ability to generate central respiratory activity in vitro persists. Replacing the normal medium which bathed the preparation by a medium containing 5-HT increased the respiratory frequency (RF) within 2-3 min in a dose-dependent manner in both D18 and D20-21 fetuses but the effect was particularly drastic at D18. Applying a medium containing the 5-HT antagonist, methysergide, to block the effect of endogenous 5-HT, if any, reduced the RF within 2-3 min and the reduction was especially drastic at D18 where respiratory arrests occurred for several minutes in most of the experiments. Applying a medium containing either the 5-HT reuptake inhibitor fluoxetine to potentiate the effect of endogenous 5-HT or the 5-HT precursor, L-tryptophan, to activate 5-HT biosynthesis mechanisms, increased the RF. To define the type of 5-HT receptors involved in the modulation of the RF, experiments were conducted with specific 5-HT agonists and antagonists. Both 5-HT1 (8-OH-DPAT, buspirone) and 5-HT2 agonists (DOI, alpha-methyl-5-HT) increased the RF but only the 5-HT1A agonist 8-OH-DPAT was efficient at submicromolar concentrations. Applying the 5-HT1A antagonist NAN-190 alone decreased the RF and even elicited respiratory arrests while the 5-HT2 antagonist ketanserin was inefficient. NAN-190 pre-treatment blocked the increase in the RF due to 8-OH-DPAT and 5-HT. Taken as a whole these results clearly indicate that endogenous 5-HT exerts an excitatory modulation on the respiratory rhythm generator via activation of medullary 5-HT1A receptors well before birth, as soon as D18 where the modulation is particularly potent.

Dopaminergic control of the cough reflex as demonstrated by the effects of apomorphine

The effect of apomorphine on the cough reflex induced by electrical stimulation of the superior laryngeal nerve was studied in cats anesthetized with pentobarbital. Intravenous administration of apomorphine in doses which ranged from 0.1 to 1.0 mg/kg decreased the number of coughs in a dose-dependent manner. Haloperidol (0.3 mg/kg i.v.) did not significantly change the number of coughs. However, haloperidol administered 15 min prior to administration of apomorphine abolished the apomorphine-induced decrease in the number of coughs. These results suggest that dopaminergic mechanisms could have an important role in the regulation of the cough reflex.

Dopaminergic control of respiration as shown by effects of 4-aminopyridine

The dopaminergic control of respiration in conscious and urethane-anaesthetized rabbits, was studied by comparing the respiratory effects of 4-aminopyridine alone (4-AP; 1 mg/kg i.v.) and those after the administration of dopamine antagonists (domperidone and haloperidol; 1 mg/kg each). The respiratory rate in conscious rabbits was increased by 4-AP. After domperidone this increase was reduced and preceded by a transient decrease. In spontaneously breathing, anesthetized rabbits there was a transient reduction after which the respiratory rate was increased by 4-AP; tidal volume was affected in an inverse manner. After domperidone, the excitatory effect of 4-AP on respiratory rate and the inhibitory effect on tidal volume were blocked. The effects of 4-AP on respiratory rate were prevented by vagotomy. In anesthetized, vagotomized, paralyzed and artificially ventilated rabbits (VPV animals) the peak amplitude of the integrated phrenic nerve activity ("phrenic activity') was increased by 4-AP. After pretreatment with haloperidol this effect of 4-AP on phrenic activity was reduced while the respiratory rate was now increased. In VPV animals with denervated carotid bodies the excitatory effect of 4-AP on phrenic activity was strongly enhanced and respiratory rate was increased. These effects were slightly reduced but not blocked by haloperidol. It is concluded that endogenous dopamine is involved in the control of respiration through effects on peripheral mechanisms (inhibition of inspiratory activity and enhancement of respiratory rate) as well as on central mechanisms (stimulation of inspiratory activity and reduction of respiratory rate).

Development of methionine-enkephalin in microdissected areas of the rabbit brain

Microdissected areas of the rabbit brain were isolated at prenatal day E-29, postnatal days P-3, 7, 14, 21, 2 months and adults. Methionine-enkephalin (ME) was assayed by RIA and ME concentration [ME] was expressed relative to the protein content of the extracted brain tissues. In brain nuclei with important roles in respiratory control [ME] was higher in prenatal and early postnatal life than in adults. In contrast, the prenatal and early postnatal [ME] levels in other nuclei were lower than or equal to adult values. These data suggest an important and changing role for ME in respiratory control throughout development. Early high [ME] levels within brainstem respiratory control nuclei may contribute to the newborn's increased susceptibility to respiratory depression.

Biogenic amine turnover in newborn and adult rabbit brainstem nuclei after pargyline administration

Following the administration of the monoamine oxidase inhibitor, pargyline, turnover rates of the biogenic amines norepinephrine (NE), dopamine (DA) and serotonin (5HT) were determined in discrete brainstem nuclei: substantia nigra (SN-A9), dorsal raphe (dr), nucleus gigantocellularis (rgi), locus coeruleus (LC-A6), nucleus ambiguus (n amb) and nucleus tractus solitarius (nts) of young and adult rabbits. The initial concentration of the amines varied markedly among the various nuclei studied, with higher values predominating in the older animals. The turnover rates for NE and DA in the rgi and LC were lower in young animals. The turnover rates for DA in the dr and nts were greater in the young animals. In addition, young rabbits had higher turnover rates for 5HT in the nts. The average turnover times for NE and 5HT were longer for the young animals (17.5 h vs 4.1 h) and (8.3 h vs 3.5 h) respectively. These data point to maturational differences in neurochemistry which may aid in elucidating possible mechanisms of respiratory instability in newborns.