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Query: UMLS:C0020440 (
hypercapnia
)
7,939
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
The respiratory and psychomotor effects of a single oral dose of meptazinol (200 mg) and dextropropoxyphene (65 mg)/paracetamol (650 mg) mixture, was compared alone and in combination with ethanol (0.8 g kg-1). Peak saccade velocity following meptazinol or the dextropropoxyphene/paracetamol mixture was not significantly different from placebo. When each of the treatments was followed by ethanol administration, a significant decrease in saccade velocity (P less than 0.01) was seen. Given alone, neither of the analgesic drugs produced a significant change in the slope of the ventilatory response to
hypercapnia
.
Ethanol
did not affect the ventilatory response to
hypercapnia
when given alone or in combination with meptazinol, but when given with the dextropropoxyphene/paracetamol mixture, a significant reduction in the slope of the ventilatory response to
hypercapnia
occurred at 1.5 h (P less than 0.05) and 2 h (P less than 0.01) after administration of the analgesic drug. No pharmacokinetic interaction was demonstrated between ethanol and meptazinol or the dextropropoxyphene/paracetamol mixture in the doses used. In contrast to meptazinol, the dextropropoxyphene/paracetamol mixture interacts with ethanol on the ventilatory function.
...
PMID:Comparison of the effects of therapeutic doses of meptazinol and a dextropropoxyphene/paracetamol mixture alone and in combination with ethanol on ventilatory function and saccadic eye movements. 409 95
Ethanol
depresses the ventilatory responses to
hypercapnia
and hypoxia. We hypothesized that this ventilatory depression, like some other central nervous system effects of ethanol, might be mediated via endorphins. In a double-blind placebo-controlled study, we assessed the effect of the opiate antagonist naloxone on ventilatory responses during ethanol intoxication in 18 normal men. Standard rebreathing studies were done at baseline, after ethanol (1.5 ml/kg, p.o.), and after each of 2 intravenously administered injections. One of the injection sequences PP, NP, or PN (N = naloxone, 0.8 mg; P = placebo, 2 ml) was randomly assigned to each subject. The ventilatory responses were reduced after ethanol administration compared with those at baseline (p less than 0.05). In groups NP and PN, naloxone restored the hypercapnic response (p less than 0.05). Placebo injection did not significantly alter the response slopes. Hypoxic ventilatory responses showed the same trends but did not reach statistical significance. This study shows that naloxone reverses ethanol-induced depression of hypercapnic drive, suggesting that an opiate-mediated mechanism is responsible for this depression.
...
PMID:Naloxone reverses ethanol-induced depression of hypercapnic drive. 635 14
The respiratory depressant effects of ethanol and their potential reversibility by naloxone were studied in 10 normal subjects. Ventilatory and mouth occlusion pressure (P0.1) responses to
hypercapnia
and hypoxia without and with an inspiratory resistive load (13 cmH2O X 1(-1) X S) were measured. The resistive load detected with 50% probability (delta R50) and the exponent (n) in Stevens' psychophysical law for magnitude estimation of resistive loads were studied using standard psychophysical techniques. Each of these studies was performed before ethanol ingestion, after ethanol ingestion (1.5 ml/kg, by mouth), and then again after naloxone (0.8 mg iv).
Ethanol
increased delta R50 (P less than 0.05) and decreased n (P less than 0.05). Naloxone caused no further change in these parameters. The load compensation (Lc), defined as the ratio of loaded to unloaded response slopes, was not significantly changed after ethanol and naloxone. No correlation was found between the Lc and delta R50 or n. The ventilatory and P0.1 responses to
hypercapnia
and hypoxia with and without inspiratory resistive loading decreased after ethanol (P less than 0.05,
hypercapnia
; NS, hypoxia). After naloxone the hypercapnic ventilatory responses increased (P less than 0.05). This suggests that the respiratory depressant effects of ethanol may be mediated via endorphins.
...
PMID:Effect of ethanol and naloxone on control of ventilation and load perception. 662 28
It has been observed that traumatic brain injury (TBI) increases the susceptibility of the brain to subsequent hypoxia, and prolonged apnea occurs in ethanol (EtOH)-treated animals following brain injury. This investigation tests the hypothesis that EtOH suppresses ventilation and hypercapnic respiratory drive following TBI. Immature pigs were anesthetized with halothane and received a 2 to 3 atm fluid-percussion brain injury. Respiratory parameters, including tidal volume, frequency, ventilation (VE), and arterial blood gases were measured on 100% O2 and on 5% to 6% inspired CO2 in O2 prior to and at 10, 60, 120, and 180 minutes after TBI.
Hypercapnic
response sensitivity (S) was measured as the change in VE per mm Hg increase in PaCO2. Intracranial pressure, mean arterial blood pressure, heart rate, brain temperature, glucose, and EtOH levels were also monitored. Three groups were studied: the first group of six received EtOH (3.5 gm/kg, intragastrically) without brain injury; the second group of six received TBI without EtOH; the third group of eight received EtOH and TBI.
Ethanol
levels were 121 +/- 13 (standard error of the mean) mg/dl in the EtOH/TBI group (136 +/- 25 in the EtOH group) at the time of injury, and 175 +/- 12 mg/dl in the EtOH/TBI group (200 +/- 20 mg/dl in the EtOH group) at 120 minutes after injury. The EtOH/TBI animals had significantly lower VE and S, and higher PaCO2 following brain injury (p < 0.05, repeated-measures analysis of variance). No significant differences were identified between groups for pH, PaCO2, intracranial pressure, heart rate, brain temperature, or glucose levels.
Ethanol
intoxication leads to significant impairment of respiratory control following traumatic brain injury and may contribute to brain injury in intoxicated trauma victims.
...
PMID:Effects of ethanol on respiratory function in traumatic brain injury. 771 8
Fetal exposure to maternal alcohol intake can be harmful to the developing brain but the effects of acute exposures are less well documented. Our objective was to determine the effects of acute alcohol exposure on developing white matter and to investigate the potential role of pro-inflammatory cytokines. Fifteen pregnant ewes underwent surgery at 110.0+/-1.0 days of the 147 day gestation for fetal catheterization.
Ethanol
(1g/kg maternal weight) was administered intravenously to 8 ewes for 1h on 3 consecutive days at 116.0+/-1.0 days of gestation (0.8 of full term); 7 pregnant control ewes received saline. Fetal brains were collected at necropsy 5 days after the initial ethanol exposure and processed for structural analysis. Maternal and fetal blood ethanol concentrations reached maximal values (0.11+/-0.01 g/dL) 1h after infusions commenced, declining to zero thereafter.
Ethanol
exposure did not cause fetal hypoxemia, acidemia,
hypercapnia
, hypoglycemia or hypotension. Subcortical white matter injury, defined as microglia/macrophage infiltration, axonal disruption, increased apoptosis, astrogliosis and altered glial cell morphology, was observed in 4 of the 8 ethanol-exposed fetuses. The injury occupied 6.6-18.3% of the cross-sectional area of cerebral white matter examined and was substantial in 2/8 and modest in 2/8 ethanol-exposed fetuses. Three remaining fetuses exhibited astrogliosis and elevated levels of apoptosis in cerebral white matter. There was a positive correlation between maternal and fetal blood ethanol concentrations and the extent of brain damage. There was no significant elevation in concentrations of the pro-inflammatory cytokines tumor necrosis factor-alpha, interleukin-1beta and interleukin-6 in fetal plasma. Developing white matter in the late gestation fetus is vulnerable to acute alcohol exposure, but mechanisms remain unclear.
...
PMID:Injurious effects of acute ethanol exposure during late gestation on developing white matter in fetal sheep. 1845 53
