UMLS:C0085383 - FACTA Search

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Query: UMLS:C0085383 (hypocapnia)
1,697 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

In case of cranial trauma, early respiratory troubles either of central or peripheral origin often accelerate the deterioration of the neurological situation. The different values of PCO2, PO2, pH and alcaline reserve measured on samples of CSF in comatose patients prove the central acidosis related to metabolic and vascular disorders in the damaged areas. Our results confirm the correlation between the importance of this disturbances and the severity of the trauma. It is thus necessary to insure patients of satisfactory respiration conditions. The tracheobronchial cleansing is applicable to intubated or tracheotomized patients by an instillation of 5ml of simple or bicarbonated physiological serum 4 to 6 times a day, followed by repeated aspirations and associated to a preventive endotracheal instillation of 80 mg of Gentamycin 4 times a day. Moreover we use controlled respiration which does not modify the gazometric parameters in the CSF but which assures patients a normoxia and moderate hypocapnia with a decrease of intracranial hypertension. Treatment by controlled hyperventilation must be precocious, because the recuperation at the level of the damaged zones is very slow.
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PMID:Treatment of comatose patients by mechanical hyperventilation. 0 50

We have previoulsy shown pH compensation to be similar in CSF and arterial blood during chronic hypoxemic hypocapnia in man and pony, and postulated that the compensatory reduction in CSF [HCO3] was dependent upon corresponding changes in [HCO3]a. We tested this hypothesis in anesthetized, paralyzed dogs by determining the effects of 7 or 14 hours of hypocapnia (PaCO2 20 and 30 mm Hg), hypoxemia (PaO2 30, 38 and 48 mm Hg) and hypocapnic hypoxemia on CSF acid-base status. [hco3]a was either permitted to fall normally or was held near control levels by NaHCO3 infusion. In hypocapnia and hypoxemic hypocapnia, the decrease in [HCO3] and % pH compensation in CSF were less than or equal to that in arterial blood. Most (51-89%) of the compensatory decrease in CSF [HCO3] was prevented by preventing the corresponding reduction in [HCO3]a. This dependence of changes in CSF on plasma [HCO3] required a concurrent decrease in CSF PCO2, but was largely independent of variations in plasma pH. A minor but significant portion of the decrease in CSF [HCO3] was achieved independently of corresponding changes in [HCO3]a. The contribution of this local mechanism to CSF [HCO3] regulation increased with increasing severity of hypocapnia or hypoxemia and was usually associated with a selective increase in CSF lactate. It was concluded that [HCO3] regulation in the CSF during hypoxemic hypocapnia was primarily dependent upon, and therefore limited by, the concomitant decrease in plasma [HCO3].
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PMID:Dependence of CSF on plasma bicarbonate during hypocapnia and hypoxemic hypocapnia. 0 65

In respiratory alkalosis the fall in CSF bicarbonate is in part due to increased CSF lactate. The rest of CSF HCO3 fall may be actively regulated or as more recent evidence suggests is dependent on plasma HCO3 fall. Therefore, the relationship between plasma and CSF HCO3 changes was studied during 4 hours of respiratory alkalosis (PaCO2=20 mm Hg) in anesthetized dogs when plasma HCO3: (1) fell normally, (2) kept 'normal' by NaHCO3 infusion, (3) increased by infusing more NaHCO3, and (4) reduced by infusing HCl. In respiratory alkalosis plasma and CSF HCO3 fell 4.6 and 3.8 mEQ/L, respectively. In hypocapnia and 'normal' plasma HCO3 CSF HCO3 fell 2 mEq/L and lactate increased 1.33 mEq/L. In hypocapnia and metabolic alkalosis plasma HCO3 increased 6.5 mEq/L and CSF HCO3 remained unchanged and lactate increased 2.12 mEq/L. In combined hypocapnia and metabolic acidosis plasma HCO3 fall 10.5 mEq/L but CSF HCO3 fell 3.1 mEq/L and CSF pH returned to normal at 4 hours. Therefore CSF HCO3 fall in hypocapnia is primarily and critically dependent on the simultaneous fall in plasma HCO3 content, with a minimal contribution from CNS lactate increase. When CSF PH has returned to normal, however, CSF HCO3 fall is stopped despite further falls in plasma HCO3.
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PMID:Importance of changes in plasma HCO-3 on regulation of CSF HCO-3 in respiratory alkalosis. 0 12

In conscious cats the ventilatory response curve to physiological range of CO2 is displaced upward by hypoxia (about 45 torr), but it rises, either parallel with, or convergent on, the normoxic curve. Thus, a positive interaction of hypoxia and hypercapnic stimuli is not observed under these circumstances. However, if during the hypoxic exposure, hypocapnia is allowed to develop, the subsequently determined CO2 ventilatory response curve will shift to the left, rise steeply, particularly in the early phase, and demonstrate a positive hypoxic hypercapnic interaction. A demonstrable interactive effect was dependent on a conditioning period of hypocapnia, and this was shown to be associated with an elevated level of lactic acid to a greater degree in cerebral venous blood than in CSF or arterial blood. The interpretation is discussed without reaching a firm conclusion of mechanism, but the results emphasize how a minor change of experimental protocol affects a basic phenomenon in the chemical control of breathing.
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PMID:The role of brief hypocapnia in the ventilatory response to CO2 with hypoxia. 1 64

Using the intra-arterial 133xenon (133Xe) method, the cerebrovascular response to acute Paco2 reduction was studied in 26 unconscious, brain-injured patients subjected to controlled ventilation. The CO2 reactivity was calculated as delta in CBF/delta Paco2. The perfusion pressure was defined as the difference between mean arterial pressure and mean intraventricular pressure. Although the CO2 reactivities did not differ significantly from that in awake, normocapnic subjects, it was low in the acute phase of injury, especially in those patients with severe outcome in whom the brain-stem reflexes were often affected. An increase of the CO2 reactivity with time was observed, indicating normal response after 1-2 weeks. Chronic hypocapnia in six unconscious patients resulted in sustained CSF pH adaptation. The question whether a delay in CSF pH adapation exerts an influence on the CO2 reactivity, and the influence of cerebral lactacidosis on the CO2 response are discussed.
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PMID:The cerebrovascular CO2 reactivity during the acute phase of brain injury. 1 91

The effects of 26 h of normoxic hypocapnia (PaCO2, 31 MMHg) vs. 26 h of hypocapnia plus hypobaric hypoxia (PaCO2 32, PaO2 57 mmHg) were compared with respect to: a) CSF acid-base status; and b) the spontaneous ventilation (at PIO2 145 mmHg) which followed the imposed (voluntary) hyperventilation. For each condition of prolonged hypocapnia, PaCO2 was held constant throughout and pHa and [HCO3-]a were constant over the final 6-10 h. We assumed that measured changes in lumbar CSF acid-base status paralleled those in cisternal CSF. Spontaneous hyperventilation followed both normoxic and hypoxic hypocapnia but was significantly greater following hypoxic hypocapnia. In the CSF, pH compensation after 26 h of hyperventilation was incomplete (similar to 45-50%), was similar to that in arterial blood, and was unaffected by a superimposed hypoxemia. These data were inconsistent with current theory which proposes the regulation of CSF [HCO2] via local mechanisms and, in turn, the mediation of ventilatory acclimatization to hypoxemia and/or hypocapnia via CSF [H+]. Alternative mediators of ventilatory acclimatization were postulated, including mechanisms both dependent on and independent of "chemoreceptor" stimuli.
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PMID:Effects of moderate hypoxemia and hypocapnia on CSF [H+] and ventilation in man. 23 66

This study has assessed the regulation of arterial blood and cerebrospinal fluid acid-base status in seven healthy men, at 250 m altitude and after 5 and 10-11 days sojourn at 4,300 m altitude (PaO2 = 39 mmHg day 1 to 48 mmHg day 11). We assumed that observed changes in lumbar spinal fluid acid-base status paralleled those in cisternal CSF, under these relatively steady-state conditions. Ventilatory acclimatization during the sojourn (-14 mmHg PaCO2 at day 11) was accompanied by: 1) reductions in [HCO3-] (-5 to -7 meq/1) which were similar in arterial blood and CSF; 2) substantial, yet incomplete, compensation (70-75%) of both CSF and blood pH; and 3) a level of CSF pH which was maintained significantly alkaline (+0.05 +/- 0.01) to normoxic control values. These data at 4,300 m confirmed and extended our previous findings for more moderate conditions of chronic hypoxia. It was postulated that the magnitude and time course of pH compensation in the CSF during chronic hypoxia and/or hypocapnia are determined by corresponding changes in plasma [HCO2-].
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PMID:Incomplete compensation of CSF [H+] in man during acclimatization to high altitude (48300 M). 23 69

Magnetic resonance imaging was used to measure the effect of inhalation of 7% CO2 and hyperventilation with 60% O2 on human cranial cerebrospinal fluid volume. During CO2 inhalation there was a reduction in the cranial CSF volume ranging from 0.7-23.7 ml (mean 9.36 ml). The degree of reduction in cranial CSF volume was independent of the individual subject's increase in end-expiratory pCO2 or mean arterial blood pressure, in response to hypercapnia. During hyperventilation with high concentration oxygen the cranial CSF volume increased in all subjects (range 0.7-26.7 ml, mean 12.7 ml). The mean changes in cranial CSF volume, induced by hypercapnia and hypocapnia, were very similar to the expected reciprocal changes in cerebral blood volume.
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PMID:Changes in cranial CSF volume during hypercapnia and hypocapnia. 249 39

Part I of these studies (Artru, 1987) examined how cerebral blood volume (CBV), CSF volume, and brain tissue water and electrolytes determined CSF pressure during 4 h of hypocapnia in sedated dogs. The three groups reported were: hypocapnia (PaCO2 20 mm Hg) with no intracranial mass (group 1), intracranial mass (epidural balloon, CSF pressure 35 cm H2O) but no hypocapnia (group 2), and intracranial mass with hypocapnia used to lower CSF pressure (group 3). It was found that in dogs with an intracranial mass (group 3) the CSF pressure-lowering effect of hypocapnia was sustained for 4 h due to improved reabsorption of CSF, decrease of CSF volume to offset reexpansion of CBV and no increase in the sum of CSF volume and CBV. The present Part II studies (groups 4-8) examine the effects of anesthetics on CSF pressure during conditions like those used for group 3, namely, intracranial mass present and hypocapnia used to lower CSF pressure. When halothane or enflurane were used for anesthesia, the CSF pressure-lowering effect of hypocapnia was not sustained. CSF pressure increased from 17.3 +/- 4.7 and 19.0 +/- 4.1 cm H2O, respectively (mean +/- SD), at 10 min to 50.3 +/- 12.8 and 43.2 +/- 12.8 cm H2O, respectively at 4 h. Increase of CSF pressure was associated with increased resistance to reabsorption of CSF (Ra) and increase in the sum of CSF volume and CBV. With halothane the intracranial volume increase was comprised chiefly of cerebral blood and with enflurane the intracranial volume increase was comprised chiefly of CSF. When isoflurane, fentanyl, or thiopental were used for anesthesia, the CSF pressure-lowering effect of hypocapnia was sustained. Ra did not increase and the sum of CBV and CSF volume remained reduced.
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PMID:Reduction of cerebrospinal fluid pressure by hypocapnia: changes in cerebral blood volume, cerebrospinal fluid volume and brain tissue water and electrolytes. II. Effects of anesthetics. 313 52

Interregional differences in intracellular pH (pHi) in brain tissue, and its regulation following 1 and 5 h of respiratory alkalosis (with and without hypoxemia) were determined in N2O anesthetized dogs. Two techniques for pHi estimation were used (TCO2 and 14C-DMO) and included corrections for measured extracellular fluid (35SO4(2-)) space (ECS). Cortical pHi by the two techniques agreed closely in control and in 3 of the 4 experimental conditions, suggesting: (a) our estimation of extracellular fluid (ECF) [HCO3-] from measured CSF [HCO3-] was a valid assumption; and (b) our method had sufficient resolution to determine the magnitude of brain pHi regulation during respiratory acid-base disturbances. When moderate normoxic respiratory alkalosis (PaCO2 approximately 25 mm Hg) was imposed for 5 h, pHi (in most brain regions) was well regulated and always exceeded the incomplete regulation noted in bulk CSF. When moderate hypoxemia (PaO2 approximately 45 mm Hg) accompanied hypocapnia, pHi was more closely regulated during the early phase (1 h) of respiratory alkalosis. Increased levels of metabolic acids (especially lactic acid) were critical to brain pHi regulation during the initial hour of respiratory alkalosis and accounted for much of the independent effect of hypoxemia on pHi regulation. However, these metabolic acids remained unchanged as pHi was more completely regulated between 1 and 5 h of continued hypocapnia or hypoxic hypocapnia. This time-dependent regulation of pHi may involve some regulatory role for changed transmembrane fluxes of H+ and/or HCO3-. Significant interregional differences were observed in both pHi and in ECS; with tendencies toward more alkaline pHi and lower ECS in brain stem and white matter. With respiratory alkalosis ECS fell and intracellular fluid increased in both cortex and caudate nucleus, possibly reflecting an osmotic effect of increased metabolic acid levels or reduction in cell membrane ion pumping.
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PMID:Interregional differences in brain intracellular pH and water compartmentation during acute normoxic and hypoxic hypocapnia in the anesthetized dog. 678 4

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