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Query: UMLS:C0011570 (
depression
)
172,036
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
The effects of carbon monoxide on ventilation were studied in unanesthetized goats. Responses to single breaths of 10-25% CO in O2, which rapidly raised carboxyhemoglobin (COHb) from 5 to 60%, were considered to reflect peripheral chemoreceptor-mediated reflexes whereas responses to continuous inhalation of 1% CO in O2, which slowly raised COHb from 0 to 60%, were considered to reflect both peripheral chemoreceptor and nonperipheral chemoreceptor mechanisms. In each of six goats, single breaths of CO failed to elicit any immediate ventilatory response. However, slow buildup of
carboxyhemoglobinemia
in the same animals always elicited ventilatory stimulation (from a mean of 7.43 to 16.02 liter/min, P less than 0.001) beginning 5-6 min after onset of 1% CO in O2 inhalation when COHb saturation reached 50-60%. In eight studies of six animals HCO3- concentration fell (from 21.3 to 15.8 meq/liter; P less than 0.001) and lactate concentration rose (from 2.5 to 4.2 meq/liter; P less than 0.05) in the cisternal cerebrospinal fluid during the CO-induced hyperpnea. Additional studies ruled out ventilatory stimulation from left heart failure or enhanced chemo-sensitivity to carbon dioxide. Although the delayed hyperpnea was associated with a hyperdynamic cardiovascular response to CO, blockade of these circulatory effects with propranolol (2 mg/kg) failed to abolish the delayed hyperpnea; however, the propranolol did unmask an element of ventilatory
depression
which preceded the hyperpnea. Conclusions were: (a) hyperventilation in response to CO inhalation is not mediated by the carotid bodies; (b) the delayed hyperpnea in response to CO inhalation is primarily due to brain-cerebrospinal fluid acidosis; (c) mobilization of body CO2 stores due to the circulatory response to CO may obscure an initial
depression
of ventilation by CO.
...
PMID:Mechanism of the ventilatory response to carbon monoxide. 94 62
To assess whether endogenous opioids participate in respiratory
depression
due to brain hypoxia, we determined the ventilatory response to progressive
carboxyhemoglobinemia
(1% CO, 40% O2) before and after administration of naloxone (NLX, 0.1 mg/kg iv). Minute ventilation (VI) and ventral medullary surface pH (Vm pH) were measured in six anesthetized, peripherally chemodenervated cats. NLX consistently increased base-line hyperoxic VI from 618 +/- 99 to 729 +/- 126 ml/min (P less than 0.05). Although NLX did not alter the Vm pH response to CO [initial alkalosis, Vm pH +0.011 +/- 0.003 pH units, followed by acidosis, Vm pH -0.082 +/- 0.036 at carboxyhemoglobin (HbCO) 55%], NLX attenuated the amount of ventilatory
depression
; increasing HbCO to 55% decreased VI to 66 +/- 6% of base line before NLX and to 81 +/- 9% of base line after NLX (P less than 0.05). The difference in response after NLX was primarily the result of a linear increase in tidal volume (VT) with decreasing Vm pH (delta VT = 60.3 ml/-pH unit) which was absent before NLX. To assess whether the site of action of the endogenous opioid effect was the central chemosensors, the ventilatory and Vm pH response to progressive HbCO was determined in three additional cats before and after topical application of NLX (3 X 10(-4) M) to the ventral medullary surface. The effect of topical NLX was similar to systemic NLX; significant attenuation of the reduction in VI with increasing HbCO. We conclude that 1) endogenous opioids mediate a portion of the
depression
of ventilation due to acute brain hypoxia, and 2) this effect is probably at the central chemosensitive regions.
...
PMID:Naloxone reduces ventilatory depression of brain hypoxia. 365 30
The effects of graded brain hypoxia on respiratory cycle timing, the lung inflation reflex, and respiratory compensation for an inspiratory flow-resistive load were studied in unanesthetized goats. Two models, inhalation and CO and acute reduction of brain blood flow (BBF) were used to produce comparable levels of brain hypoxia. The lung inflation reflex was assessed as the ratio of inspiratory time of an occluded breath to that of the preceding spontaneous breath (TIoccl/TIspont). Compensation for flow-resistive loading was assessed as the effect of the load upon the airway occlusion pressure response to rebreathing CO2 (delta P 0.1/delta PCO2). Major findings were 1) severe brain hypoxia (HbCO of 60% or BBF of 42%) caused tachypnea due to a 50% or more reduction of expiratory time but only a 20% or less reduction of inspiratory time; 2) moderate
carboxyhemoglobinemia
(HbCO of 25-30%) enhanced TIoccl/TIspont from 1.5 +/- 0.1 at control to 2.1 +/- 0.1, while severe brain hypoxia (HbCO of 60% and BBF of 42%) reduced the ratio to 1.0 +/- 0.2; and 3) compensation for a flow-resistive load, manifested by increases of delta P 0.1/delta PCO2 of 75-300% in the control state, was abolished at HbCO of 45-50% and BBF of 60%. The data suggest that in unanesthetized animals brain hypoxia elicits tachypnea largely by an effect on the expiratory phase of the bulbopontine timing mechanism. The observed enhancement of the lung inflation reflex and abolition of flow-resistive load compensation are best explained by hypoxic
depression
of higher than brain stem neural function.
...
PMID:Brain hypoxia and control of breathing: neuromechanical control. 678 50
