Sexually dimorphic effects of prenatal diazepam exposure on respiratory control and the monoaminergic system of neonate and young rats.

Pregnancy is highly affected by anxiety disorders, which may be treated with benzodiazepines, especially diazepam (DZP), that can cross the placental barrier and interact with the fetal GABAergic system. We tested whether prenatal exposure to DZP promotes sex-specific postnatal changes in the respiratory control of rats. We evaluated ventilation ([Formula: see text]) and oxygen consumption ([Formula: see text] O2) in resting conditions and under hypercapnia (7% CO2) and hypoxia (10% O2) in newborn [postnatal day (P) 0-1 and P12-13)] and young (P21-22) rats from mothers treated with DZP during pregnancy. We also analyzed brainstem monoamines at the same ages. DZP exposure had minimal effects on room air-breathing variables in females, but caused hypoventilation (drop in [Formula: see text]/[Formula: see text] O2) in P12-13 males, lasting until P21-22. The hypercapnic ventilatory response was attenuated in P0-1 and P12-13 DZP-treated females mainly by a decrease in tidal volume (VT), whereas males had a reduction in respiratory frequency (fR) at P12-13. Minor changes were observed in hypoxia, but an attenuation in [Formula: see text] was seen in P12-13 males. In the female brainstem, DZP increased dopamine concentration and decreased 5-hydroxyindole-3-acetic acid (5-HIAA) and the 3,4-dihydroxyphenylacetic acid (DOPAC)/dopamine ratio at P0-1, and reduced DOPAC concentration at P12-13. In males, DZP decreased brainstem noradrenaline at P0-1. Our results demonstrate that prenatal DZP exposure reduces CO2 chemoreflex only in postnatal females and does not affect hypoxia-induced hyperventilation in both sexes. In addition, prenatal DZP alters brainstem monoamine concentrations throughout development differently in male and female rats.

Prior aerobic physical training modulates neuropeptide expression and central thermoregulation after ovariectomy in the rat.

This study compared the effects of aerobic physical training and estradiol (E2) replacement on central pathways involved with thermoregulation in ovariectomized rats. Rats were assigned to untrained ovariectomized treated with placebo (UN-OVX), untrained ovariectomized treated with E2 (E2-OVX), and trained ovariectomized (TR-OVX) groups. Tail skin temperature (TST), internal temperature (Tint), and basal oxygen consumption (VO2) were recorded. Neuronal activity, brain expression of Kiss1, NKB and Prodyn, and central norepinephrine (NE) levels were measured. UN-OVX had the highest TST. Compared to UN-OVX rats, TR-OVX and E2-OVX had lower Fos expression in the paraventricular and arcuate (ARC) nuclei, and lower double labeling for Tyrosine Hydroxylase and Fos in the brainstem. Compared to UN-OVX, only TR-OVX group exhibited lower kisspeptin (Kiss1), neurokinin B (NKB), and prodynorphin expression in the ARC and higher central NE levels. Aerobic physical training before menopause may prevent the heat dissipation imbalance induced by reduction of E2, through central NE release, modulation of Kiss1, NKB and prodynorphin expression in neurons from ARC nucleus.

Embryonic Thermal Manipulation Affects Ventilation, Metabolism, Thermal Control and Central Dopamine in Newly Hatched and Juvenile Chicks.

The first third of incubation is critical for embryonic development, and environmental changes during this phase can affect the physiology and survival of the embryos. We evaluated the effects of low (LT), control (CT), and high (HT) temperatures during the first 5 days of incubation on ventilation ( V . E ), body temperature (Tb), oxygen consumption ( V . O2), respiratory equivalent ( V . E / V . O2), and brain monoamines on 3-days-old (3d) and 14-days-old (14d) male and female chickens. The body mass of LT animals of both ages and sexes was higher compared to HT and CT animals (except for 3d males). The heart mass of 14d HT animals was higher than that of CT animals. Thermal manipulation did not affect V . E , V . O2 or V . E / V . O2 of 3d animals in normoxia, except for 3d LT males V . E , which was lower than CT. Regarding 14d animals, the HT females showed a decrease in V . E and V . O2 compared to CT and LT groups, while the HT males displayed a lower V . O2 compared to CT males, but no changes in V . E / V . O2. Both sexes of 14d HT chickens presented a greater Tb compared to CT animals. Thermal manipulations increased the dopamine turnover in the brainstem of 3d females. No differences were observed in ventilatory and metabolic parameters in the 3d animals of either sexes, and 14d males under 7% CO2. The hypercapnic hyperventilation was attenuated in the 14d HT females due to changes in V . O2, without alterations in V . E . The 14d LT males showed a lower V . E , during hypercapnia, compared to CT, without changes in V . O2, resulting in an attenuation in V . E / V . O2. During hypoxia, 3d LT females showed an attenuated hyperventilation, modulated by a higher V . O2. In 14d LT and HT females, the increase in V . E was greater and the hypometabolic response was attenuated, compared to CT females, which resulted in no change in the V . E / V . O2. In conclusion, thermal manipulations affect hypercapnia-induced hyperventilation more so than hypoxic challenge, and at both ages, females are more affected by thermal manipulation than males.