Renata C.H. Barros

Cardiovascular responses to chemoreflex activation with potassium cyanide or hypoxic hypoxia in awake rats.

Although intravenous (iv) injection of potassium cyanide (KCN) activates the arterial chemoreflex, it has been questioned whether cytotoxic hypoxia reproduces a physiological stimulus such as hypoxic hypoxia (low inspired O2 tension). Thus, the goal of the present study was to compare the cardiovascular responses elicited by intravenous injection of KCN to those caused by hypoxic hypoxia in awake rats before and after bilateral ligature of carotid body arteries. We tested the hypothesis that hypoxic hypoxia activates the cardiovascular chemoreflex just as KCN does, causing an increase in arterial pressure and bradycardia. Intact adult Wistar rats received an intravenous injection of KCN (160 microg/kg) and were exposed to hypoxic hypoxia (7-5% O2 breathing) for 10-15 s at random while mean arterial pressure (MAP) and heart rate (HR) were measured. After the experiments, the animals were submitted to bilateral ligature of carotid body arteries or sham operation and the protocol was repeated on the subsequent day. Before surgery, all rats showed an abrupt rise in arterial pressure accompanied by a marked bradycardia in response to KCN or hypoxic hypoxia, with a very similar pattern. After surgery, these responses persisted only in the sham-operated group and were totally abolished in the ligature group. In conclusion, our data show that KCN is an appropriate stimulus to activate arterial chemoreflex because its cardiovascular responses are comparable to those induced by hypoxic hypoxia. Thus, the use of KCN as a tool to evaluate different aspects of the complex pattern of cardiovascular, respiratory, and behavioural responses to chemoreflex activation seems to be physiologically acceptable.

Role of central adenosine in the respiratory and thermoregulatory responses to hypoxia

No reports are available about the role of central adenosine in the respiratory and thermoregulatory responses to hypoxia in conscious rats. We therefore measured ventilation (VE) and body temperature (Tb) before and after intracerebroventricular injection of saline or aminophylline (adenosine antagonist), followed by a 30-min period of hypoxia exposure. Aminophylline did not change VE or Tb during normoxia; however, during hypoxia, it caused a significant increase in VE, and significantly attenuated hypoxic hypothermia. The present data indicate that central adenosine has an inhibitory effect on hypoxic hyperventilation and partially causes hypoxic hypothermia, suggesting that the ventilatory and metabolic interaction during hypoxia does not involve opposing mechanisms.

Evidence for thermoregulation by dopamine D1 and D2 receptors in the anteroventral preoptic region during normoxia and hypoxia

Hypoxia causes a regulated decrease in body temperature (Tb), a response that has been called anapyrexia. Stimulation of dopamine receptors in the central nervous system (CNS) reduces Tb in rats, and dopamine D1 and D2 receptors seem to be involved in this response. Thus, we predicted that injection of SCH 23390 and haloperidol, D1 and partly D2 receptor antagonists, respectively, into the anteroventral preoptic region (AVPO, the thermointegrative region of the CNS) would lessen the hypoxia-induced anapyrexia. We measured Tb of conscious Wistar rats before and after injection of SCH 23390 (50 and 100 ng/100 nl) or haloperidol (50 e 500 ng/100 nl) or their respective vehicles (saline and DMSO 5%) into the AVPO followed by 30 min of hypoxia (7% O2). Vehicles and the lower doses of SCH 23390 and haloperidol had no effect on Tb during normoxia or hypoxia. The higher doses of SCH 23390 and haloperidol attenuated (P<0.05) the drop in Tb elicited by hypoxia. However, this higher haloperidol dose also increased Tb during normoxia. The present data is consistent with the notion that dopamine is an important thermoregulatory neurotransmitter in a way that D2 receptors are mainly involved with maintenance of Tb in euthermia, while D1 receptors are activated to induce hypoxic anapyrexia in the AVPO.

Tolerance to lipopolysaccharide is related to the nitric oxide pathway

Repeated administration of lipopolysaccharide (LPS) induces a refractory state to its usual pyrogenic effects which is called endotoxin tolerance. We tested the hypothesis that nitric oxide (NO) participates in the endotoxin tolerance. Single injection of LPS resulted in an elevation in body temperature (Tb), whereas a significant reduction of the thermoregulatory response to LPS was observed to repeated administration of LPS (administered at 48 h intervals). Intracerebroventricular (i.c.v.) injection of L-NAME (a non-selective NO inhibitor of nitric oxide synthesis) markedly enhanced the febrile response to LPS in tolerant rats. The data suggest that NO pathway in the central nervous system plays a role in endotoxin tolerance.

Respiratory and body temperature modulation by adenosine A1 receptors in the anteroventral preoptic region during normoxia and hypoxia

The present study was undertaken to investigate adenosine as a simultaneous mediator of hypoxia-induced hyperventilation and regulated hypothermia in the anteroventral preoptic region (AVPO), the thermointegrative region of the central nervous system (CNS). Accordingly, we predicted that injection of aminophylline and DPCPX, non-selective and A(1) receptor antagonists, respectively, into the AVPO would exacerbate the ventilatory response and lessen the drop in body temperature (T(b)) caused by hypoxia. We measured ventilation (V ) and T(b) of conscious Wistar rats before and after AVPO injection of aminophylline (1 and 10 microg/100 nL) or DPCPX (17.5 and 175 ng/100 nL), or their respective vehicles, followed by 30 min of hypoxia (7% O(2)). Vehicles and the lower doses of both antagonists had no effect on V and T(b) during normoxia or hypoxia. The higher doses of aminophylline and DPCPX increased (P<0.05) the hypoxia-induced hyperventilation, whereas the drop in T(b) elicited by hypoxia was attenuated (P<00.05) by DPCPX only. This higher DPCPX dose also increased T(b) during normoxia. The present data is consistent with the notion that adenosine plays an inhibitory role in respiratory and metabolic regulation, in a way that A(1) receptors stimulation in the AVPO inhibits ventilatory drive during hypoxia and tonically modulates basal T(b).

Respiratory and metabolic responses of the spiny rats Proechimys yonenagae and P. iheringi to CO2

The recently described burrow-dwelling Proechimys yonenagae from the Brazilian semiarid caatinga was compared to P. iheringi from the Brazilian rain forest of Mata Atlântica in terms of interactions between body temperature (Tb), ventilation (VE) and oxygen consumption (V(O2)) during hypercapnia (5 or 10% CO2). Wistar rats were also used as a control. VE was measured by plethysmography, Tb by inserting a probe into the colon, and V(O2) by a close-flow system. During air breathing, VE did not differ between the rodents, Wistar Tb was elevated compared to P. yonenagae, and the V(O2) values of P. yonenagae and P. iheringi were significantly lower than those of Wistar rats. Hypercapnia caused hyperventilation in the three rodents, hypothermia in P. yonenage and Wistar rats, but no change in V(O2) was observed in any of the rodents. The hypercapnia-induced hyperventilation may be a major factor producing heat loss. This effect was independent of V(O2). Comparisons of the two spiny rat species suggest little adaptation of P. yonenagae to hypercapnia in burrows.

nNOS is involved in behavioral thermoregulation of newborn rats during hypoxia

The present study was undertaken to investigate the role of nitric oxide (NO) pathway in the behavioral thermoregulation of newborn rats in cold and hypoxia. We predicted that injection of L-NAME (non-selective NO synthase (NOS) inhibitor) and SMTC (neuronal NOS (nNOS) inhibitor) would restore the huddling behavior and eliminate the reduction of Tb caused by hypoxia. Experiments were performed on Wistar rat pups of 7-9 days old. We measured Tb and analyzed the huddling behavior by means of the calculation of the total surface area occupied by 5 pups and the number of single pups grouped in the center of a chamber at 20 degrees C, before and after L-NAME, SMTC or their respective vehicles (D-NAME and saline) s.c. injections. Subsequently, the pups were exposed to hypoxia (10% O(2)) during 30 min, whereas control animals were kept under normoxia. The experiments were monitored by a digital camera. All animals were hypothermic when exposed to 20 degrees C. There was no significant difference in Tb, total area and number of single pups in normoxia after treatments. During hypoxia, the drop in Tb was higher in control groups, and this effect was attenuated by L-NAME and SMTC injections. Hypoxia increased the area occupied by the pups in saline, D-NAME and L-NAME groups, while SMTC attenuated this response. The data indicate that NO pathway is involved in the inhibition of huddling behavior and in the reduction of Tb caused by hypoxia, but plays no role during normoxia. Furthermore, NO seems to arise from the nNOS isoform.