Cancan Zhang

Activation of Opioid μ Receptors in Caudal Medullary Raphe Region Inhibits the Ventilatory Response to Hypercapnia in Anesthetized Rats

Background: Opioids, extensively used as analgesics, markedly depress ventilation, particularly the ventilatory responsiveness to hypercapnia in humans and animals predominantly via acting on &mgr; receptors. The medullary raphe region (MRR) contains abundant &mgr; receptors responsible for analgesia and is also an important central area involving carbon dioxide chemoreception and contributing to the ventilatory responsiveness to hypercapnia. Therefore, the authors asked whether activation of &mgr; receptors in the caudal, medial, or rostral MRR depressed ventilation and the response to hypercapnia, respectively. Methods: Experiments were conducted in 32 anesthetized and spontaneously breathing rats. Ventilation and it response to progressive hypercapnia were recorded. The slopes obtained from plotting minute ventilation, respiratory frequency, and tidal volume against the corresponding levels of end-tidal pressure of carbon dioxide were used as the indices of the respiratory responsiveness to carbon dioxide. DAMGO ([d-Ala2, N-Me-Phe4, Gly-ol]-enkephalin), a &mgr;-receptor agonist, was systemically administered (100 &mgr;g/kg) before and/or after local injection of CTAP (D-Phe-Cys-Tyr-D-Trp-Arg-Thr-Pen-Thr-NH2) (100 ng/100 nl), a &mgr;-receptor antagonist, into the caudal MRR, or locally administered (35 ng/100 nl) into the MRR subnuclei. Results: The authors found that systemic DAMGO significantly inhibited ventilation and the response to carbon dioxide by 20% and 31%, respectively, and these responses were significantly diminished to 11% and 14% after pretreatment of the caudal MRR with CTAP. Local administration of DAMGO into the caudal MRR also reduced ventilation and the response to carbon dioxide by 22% and 28%, respectively. In sharp contrast, these responses were not observed when the DAMGO microinjection was made in the middle MRR or rostral MRR. Conclusions: These results lead to the conclusion that &mgr; receptors in the caudal MRR rather than the middle MRR or rostral MRR are important but not exclusive for attenuating the hypercapnic ventilatory response.

Activation of opioid μ-receptors in the commissural subdivision of the nucleus tractus solitarius abolishes the ventilatory response to hypoxia in anesthetized rats.

Background:The commissural subnucleus of the nucleus tractus solitarius (comNTS) is a key region in the brainstem responsible for the hypoxic ventilatory response (HVR) because it contains the input terminals of the carotid chemoreceptor. Because opioids inhibit the HVR via activating central &mgr;-receptors that are expressed abundantly in the comNTS, the authors of the current study asked whether activating local &mgr;-receptors attenuated the carotid body-mediated HVR. Methods:To primarily stimulate the carotid body, brief hypoxia (100% N2) and hypercapnia (15% CO2) for 10 s and/or intracarotid injection of NaCN (10 &mgr;g/100 &mgr;l) were performed in anesthetized and spontaneously breathing rats. These stimulations were repeated after: (1) microinjecting three doses of &mgr;-receptor agonist [d-Ala2, N-Me-Phe4, Gly-ol]-Enkephalin (DAMGO) (approximately 3.5 nl) into the comNTS; (2) carotid body denervation; and (3) systemic administration of DAMGO (300 &mgr;g/kg) without and with previous intracomNTS injection of d-Phe-Cys-Tyr-d-Trp-Arg-Thr-Pen-Thr-NH2, a &mgr;-receptor antagonist. Results:Study results showed that DAMGO at 0.25 and 2.5, but not 0.025 mM, caused a similar decrease in baseline ventilation (approximately 12%). DAMGO at 0.25 mM largely reduced (64%) the HVR, whereas DAMGO at 2.5 mM abolished the HVR (and the VE response to NaCN) and moderately attenuated (31%) the hypercapnic ventilatory response. Interestingly, similar HVR abolition and depression of the hypercapnic ventilatory response were observed after carotid body denervation. Blocking comNTS &mgr;-receptors by d-Phe-Cys-Tyr-d-Trp-Arg-Thr-Pen-Thr-NH2 significantly attenuated the HVR depression by systemic DAMGO with little change in the DAMGO modulatory effects on baseline ventilation and the hypercapnic ventilatory response. Conclusion:The data suggest that opioids within the comNTS, via acting on &mgr;-receptors, are able to abolish the HVR by affecting the afferent pathway of the carotid chemoreceptor.

Opioid μ-receptors in medullary raphe region affect the hypoxic ventilation in anesthetized rats

Opioids can attenuate the peripheral chemoreceptor-mediated hypoxic ventilatory response (HVR) by acting on central mu-type opioid receptors. Since the medullary raphe region (MRR) expresses abundant mu-receptors and participates in modulating HVR, we tested the role of mu-receptors within the caudal, medial, and rostral MRR (cMRR, mMRR, and rMRR) in modulating the HVR. We recorded cardiorespiratory activities and their responses to isocapnic hypoxia in anesthetized rats before and after local microinjection of DAMGO into the MRR, and intravenous administration of DAMGO (100 microg/kg) alone or coupled with a previous local injection of CTAP. Microinjecting DAMGO into the cMRR or mMRR but not the rMRR significantly attenuated the HVR. However, systemic DAMGO-induced HVR attenuation was not significantly affected by pretreating the cMRR and mMRR with CTAP. Our data suggest that cMRR and mMRR mu-receptors are capable of depressing the HVR, while their contribution to the attenuated HVR by systemic DAMGO is limited.

Activation of opioid μ-receptors in medullary raphe depresses sighs

Sighs, a well-known phenomenon in mammals, are substantially augmented by hypoxia and hypercapnia. Because (d-Ala(2),N-Me-Phe(4),Gly-ol)-enkephalin (DAMGO), a mu-receptor agonist, injected intravenously and locally in the caudal medullary raphe region (cMRR) decreased the ventilatory response to hypoxia and hypercapnia, we hypothesized that these treatments could inhibit sigh responses to these chemical stimuli. The number and amplitude of sighs were recorded during three levels of isocapnic hypoxia (15%, 10%, and 5% O(2) for 1.5 min) or hypercapnia (3%, 7%, and 10% CO(2) for 4 min) to test the dependence of sigh responses on the intensity of chemical drive in anesthetized and spontaneously breathing rats. The role of mu-receptors in modulating sigh responses to 10% O(2) or 7% CO(2) was subsequently evaluated by comparing the sighs before and after 1) intravenous administration of DAMGO (100 microg/kg), 2) microinjection of DAMGO (35 ng/100 nl) into the cMRR, and 3) intravenous administration of DAMGO after microinjection of d-Phe-Cys-Tyr-d-Trp-Arg-Thr-Pen-Thr-NH(2) (CTAP, 100 ng/100 nl), a micro-receptor antagonist, into the cMRR. Hypoxia and hypercapnia increased the number, but not amplitude, of sighs in a concentration-dependent manner, and the responses to hypoxia were significantly greater than those to hypercapnia. Systemic and local injection of DAMGO into the cMRR predominantly decreased the number of sighs, while microinjection into the rostral and middle MRR had no or limited effects. Microinjecting CTAP into the cMRR significantly diminished the systemic DAMGO-induced reduction of the number of sighs in response to hypoxia, but not to hypercapnia. Thus we conclude that hypoxia and hypercapnia elevate the number of sighs in a concentration-dependent manner in anesthetized rats, and this response is significantly depressed by activating systemic mu-receptors, especially those within the cMRR.

IL-1β acutely increases pulmonary SP and permeability without associated changes in airway resistance and ventilation in anesthetized rats.

Bronchopulmonary C-fibers (PCFs), when activated, promote substance P (SP) release, increase microvascular leak, and produce bronchoconstriction and apnea. IL-1β administered systemically or locally into the pulmonary parenchyma stimulates PCFs. Thus, we tested whether right atrial bolus injection or aerosol inhalation of IL-1β, to mainly stimulate PCFs, would acutely affect pulmonary SP level and vascular permeability, airway resistance (R(L)), and ventilation in anesthetized rats. Our results showed that 30min after IL-1β injection (2-6 μg kg⁻¹), SP levels and Evans blue extravasation in bronchoalveolar lavage fluid were markedly increased and these responses were eliminated or largely reduced in neonatal capsaicin-treated rats. In contrast, neither injection nor inhalation of IL-1β (5-15 μg ml⁻¹) significantly altered R(L) and ventilation. Additionally, the capsaicin-evoked (4 μg kg⁻¹, i.v.) apneic response was unaffected by IL-1β treatment. Our data suggest that IL-1β, as administered in this study, can acutely increase pulmonary SP and vascular permeability, likely via stimulating PCFs, with little impact on R(L) and ventilation.

Isoflurane depolarizes bronchopulmonary C neurons by inhibiting transient A-type and delayed rectifier potassium channels

Inhalation of isoflurane (ISO), a widely used volatile anesthetic, can produce clinical tachypnea. In dogs, this response is reportedly mediated by bronchopulmonary C-fibers (PCFs), but the relevant mechanisms remain unclear. Activation of transient A-type potassium current (IA) channels and delayed rectifier potassium current (IK) channels hyperpolarizes neurons, and inhibition of both channels by ISO increases neural firing. Due to the presence of these channels in the cell bodies of rat PCFs, we determined whether ISO could stimulate PCFs to produce tachypnea in anesthetized rats, and, if so, whether this response resulted from ISO-induced depolarization of the pulmonary C neurons via the inhibition of IA and IK. We recorded ventilatory responses to 5% ISO exposure in anesthetized rats before and after blocking PCF conduction and the responses of pulmonary C neurons (extracellularly recorded) to ISO exposure. ISO-induced (1mM) changes in pulmonary C neuron membrane potential and IA/IK were tested using the perforated patch clamp technique. We found that: (1) ISO inhalation evoked a brief tachypnea (∼7s) and that this response disappeared after blocking PCF conduction; (2) the ISO significantly elevated (by 138%) the firing rate of most pulmonary C neurons (17 out of 21) in the nodose ganglion; and (3) ISO perfusion depolarized the pulmonary C neurons in the vitro and inhibited both IA and IK, and this evoked-depolarization was largely diminished after blocking both IA and IK. Our results suggest that ISO is able to stimulate PCFs to elicit tachypnea in rats, at least partly, via inhibiting IA and IK, thereby depolarizing the pulmonary C neurons.

Inhalation of the nerve gas sarin impairs ventilatory responses to hypercapnia and hypoxia in rats

Sarin, a highly toxic nerve gas, is believed to cause bronchoconstriction and even death primarily through respiratory failure; however, the mechanism underlying the respiratory failure is not fully understood. The goals of this study were to ascertain whether sarin affects baseline ventilation (VE) and VE chemoreflexes as well as airway resistance and, if so, whether these changes are reversible. Four groups of F344 rats were exposed to vehicle (VEH) or sarin at 2.5, 3.5, and 4.0 mg h m(-3) (SL, SM, and SH, respectively). VE and VE responses to hypercapnia (7% CO2) or hypoxia (10% O2) were measured by plethysmography at 2 h and 1, 2, and 5 days after VEH or sarin exposure. Total pulmonary resistance (RL) also was measured in anesthetized VEH- and SH-exposed animals 2 h after exposure. Our results showed that within 2 h after exposure 11% of the SM- and 52% of the SH- exposed groups died. Although the SM and SH significantly decreased hypercapnic and hypoxic VE to similar levels (64 and 69%), SH induced greater respiratory impairment, characterized by lower baseline VE (30%; P<0.05), and total loss of the respiratory frequency response to hypercapnia and hypoxia. VE impairment recovered within 1-2 days after sarin exposure; interestingly, SH did not significantly affect baseline RL. Moreover, sarin induced body tremors that were unrelated to the changes in the VE responses. Thus, LC50 sarin causes a reversible impairment of VE that is not dependent on the sarin-induced body tremors and not associated with changes in RL.

Contribution of central μ-receptors to switching pulmonary C-fibers-mediated rapid shallow breathing into an apnea by fentanyl in anesthetized rats.

UNLABELLED Our previous study has shown that activating peripheral μ-receptors is necessary for switching the bronchopulmonary C-fibers (PCFs)-mediated rapid shallow breathing (RSB) into an apnea by systemic administration of fentanyl. The brainstem nuclei, such as the medial nucleus tractus solitarius (mNTS) and the pre-Botzinger complex (PBC), are required for completing the PCF-mediated respiratory reflexes. Moreover, these areas contain abundant μ-receptors and their activation prolongs expiratory duration (T(E)). Thus, we asked if central μ-receptors, especially those in the mNTS and PBC, are involved in fully expressing this RSB-apnea switch by fentanyl. In anesthetized rats, the cardiorespiratory responses to right atrial injection of phenylbiguanide (PBG, 3-6μg/kg) were repeated after: (1) fentanyl (iv), a μ-receptor agonist, alone (8μg/kg, iv); (2) fentanyl following microinjection of naloxone methiodide (NXM, an opioid receptor antagonist) into the cisterna magna (10μg/4μl); (3) the bilateral mNTS (10mM, 20nl); or (4) PBC (10mM, 20nl). Our results showed that PBG shortened T(E) by 37±6% (RSB, from 0.41±0.05 to 0.26±0.03s, P<0.01), but it markedly prolonged T(E) by 5.8-fold (an apnea, from 0.50±0.04s to 2.9±0.57s, P<0.01) after fentanyl (iv). Pretreatment with NXM injected into the cisterna magna or the PBC, but not the mNTS, prevented the fentanyl-induced switch. This study, along with our previous results mentioned above, suggests that although peripheral μ-receptors are essential for triggering the fentanyl-induced switch, central μ-receptors, especially those in the PBC, are required to fully exhibit such switch. SUMMARY STATEMENT Our results suggest that the activation of central μ-receptors, especially those in the pre-Botzinger complex, is required for switching the pulmonary C-fiber-mediated rapid shallow breathing into an apnea by systemic administration of fentanyl.

Passive limb movement augments ventilatory response to CO2 via sciatic inputs in anesthetized rats.

Passive limb movement (PLM) in humans induces a phasic hyperpnea, but the underlying physiological mechanisms remain unclear. We asked whether PLM in anesthetized rats would produce a similar phasic hyperpnea associated with an augmented ventilatory (V(E)) response to CO(2) that is dependent on sciatic afferents. The animals underwent 5 min threshold PLM, 3 min hypercapnia (5% CO(2)), and their combination (CO(2) exposure at the end of 2nd min of 5-min PLM) before and after bilateral transection of the sciatic nerves. We found that a threshold PLM evoked a phasic hyperpnea, similar to that denoted in humans, and an augmented V(E) response to CO(2). Both responses were greatly diminished by sciatic nerve transection. Moreover, similar responses were also evoked by electrically stimulating the central end of the transected sciatic nerve. Our findings suggest an ability of the sciatic afferents to augment the V(E) response to CO(2) that likely contributes to the PLM-induced hyperpnea.