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Query: UMLS:C0020440 (
hypercapnia
)
7,939
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Recent experimental studies reported by several independent groups demonstrated that in the initial interventions of cardiopulmonary resuscitation (CPR), airway protection (A) and artificial breathing (B) are not essential for successful recovery from cardiac arrest. In this study, we reviewed and compared those reports to investigate individual effects of A and B on initial CPR. Airway protection: Spontaneous gasping during cardiac arrest is accompanied by upper airway protective reflexes such as head tilt and open mouth.
Gasping
promoted CO2 elimination from the nose in animals without A. Breathing:
Gasping
and precordial compression generated ventilation up to 150 and 100 ml.kg-1. min-1 respectively during cardiac arrest. Arterial blood gas analyses demonstrated that CPR without B developed
hypercarbia
, but maintained oxygen tensions in physiological levels. The frequency of chest compression is in the range of high frequency ventilation, which might allow for successful oxygenation regardless of limited tidal volumes. A series of experimental studies for CPR without A or B call for establishment of a simple CPR method for bystanders, namely "Just compress the chest".
...
PMID:[Potency of CPR without artificial breathing]. 909 1
Birth asphyxia represents a serious problem worldwide, resulting in 1 million deaths and an equal number of neurologic sequelae annually. It is therefore important to develop new and better ways to treat asphyxia. In the present study we tested the effect of reoxygenation with room air or 100% oxygen following experimental pneumothorax induced asphyxia on blood oxidative stress indicators, early neurologic outcome and cerebral histopathology of newborn piglets. 26 animals were studied in three experimental groups: sham-operated (SHAM, n = 6), reoxygenation with room air after pneumothorax (RORA, n = 10) and reoxygenation with 100% oxygen after pneumothorax (RO100, n = 10). In RORA and RO100 asphyxia was induced under anesthesia with bilateral intrapleural room air insufflation.
Gasping
, bradyarrhythmia, arterial hypotension, hypoxemia,
hypercarbia
and severe combined acidosis occurred 62 +/- 6 (RORA) and 65 +/- 7 min (RO100) after the start of the experiments, when the pneumothorax was relieved and ten min of reoxygenation period was started with mechanical ventilation with room air (RORA) or 100% oxygen (RO100). Then the spontaneously breathing animals were followed on room air during the next three hours. Blood oxidative stress indicators--as oxidized and reduced glutathione, plasma hemoglobin and malondialdehyde concentrations--were also measured at different stages of the experiments and early neurologic examinations (neurological score: 20 = normal, 5 = brain dead) were performed at the end of the study. Then the brains were fixed and stained. In SHAM blood gases and acid/base status differed significantly from values measured in RORA and RO100. In RO100 PaO2 was significantly higher at 5 (13.8 +/- 1.8 kPa) and 10 min (13.2 +/- 2.0 kPa) than in RORA (8.7 +/- 0.9, 9.2 +/- 1.0 kPa), respectively. All the measures of oxidative stress indicators remained unchanged in the study groups (SHAM, RORA, RO100). Neurologic examination scores from SHAM were 18 +/- 0, from RORA 13.5 +/- 1.0 and from RO100 9.5 +/- 1.3 (significant differences between SHAM and RORA and RO100, significant difference between RORA and RO100). Cerebral histopathology showed marked damage with similar severity in both asphyxiated groups. We conclude that blood oxidative stress indicators and cerebral histopathology did not differ significantly after 10 min reoxygenation either with room air or with 100% oxygen following pneumothorax induced asphyxia, but reoxygenation with 100% oxygen might impair the early neurologic outcome of newborn pigs.
...
PMID:[Reoxigenation after neonatal asphyxia with 21% or 100% oxygen in piglets]. 1114 59
Birth asphyxia is a serious problem worldwide, resulting in 1 million deaths and an equal number of neurologic sequelae annually. It is therefore important to develop new and better ways to treat asphyxia. In the present study we tested the effects of reoxygenation with room air or with 100% oxygen (O2) after experimental pneumothorax-induced asphyxia on the blood oxidative stress indicators, early neurologic outcome, and cerebral histopathology of newborn piglets. Twenty-six animals were studied in three experimental groups: 1) sham-operated animals (SHAM, n = 6), 2) animals reoxygenated with room air after pneumothorax (R21, n = 10), and 3) animals reoxygenated with 100% O2 after pneumothorax (R100, n = 10). In groups R21 and R100, asphyxia was induced under anesthesia with bilateral intrapleural room air insufflation.
Gasping
, bradyarrhythmia, arterial hypotension, hypoxemia,
hypercarbia
, and combined acidosis occurred 62 +/- 6 min (R21) or 65 +/- 7 min (R100; mean +/- SD) after the start of the experiments; then pneumothorax was relieved, and a 10-min reoxygenation period was started with mechanical ventilation with room air (R21) or with 100% O2 (R100). The newborn piglets then breathed room air spontaneously during the next 3 h. Blood oxidative stress indicators (oxidized and reduced glutathione, plasma Hb, and malondialdehyde concentrations) were measured at different stages of the experiments. Early neurologic outcome examinations (neurologic score of 20 indicates normal, 5 indicates brain-dead) were performed at the end of the study. The brains were next fixed, and various regions were stained for cerebral histopathology. In the SHAM group, the blood gas and acid-base status differed significantly from those measured in groups R21 and R100. In group R100, arterial PO2 was significantly higher after 5 (13.8 +/- 5.6 kPa) and 10 min (13.2 +/- 6.3 kPa) of reoxygenation than in group R21 (8.7 +/- 2.8 kPa and 9.2 +/- 3.1 kPa). The levels of all oxidative stress indicators remained unchanged in the study groups (SHAM, R21, and R100). The neurologic examination score in the SHAM group was 18 +/- 0, in group R21 it was 13.5 +/- 3.1, and in group R100 it was 9.5 +/- 4.1 (significant differences between SHAM and R21 or R100, and between R21 and R100). Cerebral histopathology revealed marked damage of similar severity in both asphyxiated groups. We conclude that the blood oxidative stress indicators and cerebral histopathology did not differ significantly after a 10-min period of reoxygenation with room air or with 100% O2 after pneumothorax-induced asphyxia, but reoxygenation with 100% O2 might impair the early neurologic outcome of newborn piglets.
...
PMID:Impaired early neurologic outcome in newborn piglets reoxygenated with 100% oxygen compared with room air after pneumothorax-induced asphyxia. 1138 43
The perfused in situ juvenile rat preparation produces phrenic discharge patterns comparable to eupnea and gasping in vivo. These ventilatory patterns of eupnea and gasping differ in multiple aspects, including most prominently the rate of rise of inspiratory activity. Because gasping, but not eupnea, appeared similar after vagotomy in spontaneous breathing preparations, it has been assumed that gasping was unresponsive to afferent stimuli from pulmonary stretch receptors. In the present study, efferent activity of the phrenic nerve was recorded during eupnea and gasping in the in situ juvenile rat preparation.
Gasping
was induced in hypoxic-
hypercapnia
or ischemia. An increase in the pressure of tonic lung inflation from 1 to 10 cmH2O caused a prolongation of the duration between phrenic bursts in both eupnea or gasping. Bilateral vagotomy eliminated these changes. We conclude that the neural substrate mediating the Hering-Breuer reflex is retained in the in situ preparation and that the brain stem circuitry generating the respiratory patterns responds to tonic activation of pulmonary stretch receptors in a similar manner in eupnea and gasping. These findings support the homology of eupnea-like phrenic discharge patterns in the reduced in situ preparation and eupnea in vivo and disprove the common supposition that gasping is insensitive to vagal afferent feedback from pulmonary stretch receptor mechanisms.
...
PMID:Tonic pulmonary stretch receptor feedback modulates both eupnea and gasping in an in situ rat preparation. 1262 72
In severe hypoxia or ischemia, normal eupneic breathing fails and is replaced by gasping.
Gasping
serves as part of a process of autoresuscitation by which eupnea is reestablished. Medullary neurons, having a burster, pacemaker discharge, underlie gasping. Conductance through persistent sodium channels is essential for the burster discharge. This conductance is modulated by norepinephrine, acting on alpha 1-adrenergic receptors, and serotonin, acting on 5-HT2 receptors. We hypothesized that blockers of 5-HT2 receptors and alpha 1-adrenergic receptors would alter autoresuscitation. The in situ perfused preparation of the juvenile rat was used. Integrated phrenic discharge was switched from an incrementing pattern, akin to eupnea, to the decrementing pattern comparable to gasping in hypoxic
hypercapnia
. With a restoration of hyperoxic normocapnia, rhythmic, incrementing phrenic discharge returned within 10 s in most preparations. Following addition of blockers of alpha 1-adrenergic receptors (WB-4101, 0.0625-0.500 microM) and/or blockers of 5-HT2 (ketanserin, 1.25-10 microM) or multiple 5-HT receptors (methysergide, 3.0-10 microM) to the perfusate, incrementing phrenic discharge continued. Fictive gasping was still induced, although it ceased after significantly fewer decrementing bursts than in preparations than received no blockers. Moreover, the time for recovery of rhythmic activity was significantly prolonged. This prolongation was in excess of 100 s in all preparations that received both WB-4101 (above 0.125 microM) and methysergide (above 2.5 microM). We conclude that activation of adrenergic and 5-HT2 receptors is important to sustain gasping and to restore rhythmic respiratory activity after hypoxia-induced depression.
...
PMID:Maintenance of gasping and restoration of eupnea after hypoxia is impaired following blockers of alpha1-adrenergic receptors and serotonin 5-HT2 receptors. 1816 82
