Effect of voluntary hyperventilation with supplemental CO2 on pulmonary O2 uptake and leg blood flow kinetics during moderate‐intensity exercise
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Pulmonary O2 uptake (V(O₂p)) and leg blood flow (LBF) kinetics were examined at the onset of moderate-intensity exercise, during hyperventilation with and without associated hypocapnic alkalosis. Seven male subjects (25 ± 6 years old; mean ± SD) performed alternate-leg knee-extension exercise from baseline to moderate-intensity exercise (80% of estimated lactate threshold) and completed four to six repetitions for each of the following three conditions: (i) control [CON; end-tidal partial pressure of CO2 (P(ET, CO₂)) ~40 mmHg], i.e. normal breathing with normal inspired CO2 (0.03%); (ii) hypocapnia (HYPO; P(ET, CO₂) ~20 mmHg), i.e. sustained hyperventilation with normal inspired CO2 (0.03%); and (iii) normocapnia (NORMO; P(ET, CO₂) ~40 mmHg), i.e. sustained hyperventilation with elevated inspired CO2 (~5%). The V(O₂p) was measured breath by breath using mass spectrometry and a volume turbine. Femoral artery mean blood velocity was measured by Doppler ultrasound, and LBF was calculated from femoral artery diameter and mean blood velocity. Phase 2 V(O₂p) kinetics (τV(O₂p)) was different (P < 0.05) amongst all three conditions (CON, 19 ± 7 s; HYPO, 43 ± 17 s; and NORMO, 30 ± 8 s), while LBF kinetics (τLBF) was slower (P < 0.05) in HYPO (31 ± 9 s) compared with both CON (19 ± 3 s) and NORMO (20 ± 6 s). Similar to previous findings, HYPO was associated with slower V(O₂p) and LBF kinetics compared with CON. In the present study, preventing the fall in end-tidal P(CO₂) (NORMO) restored LBF kinetics, but not V(O₂p) kinetics, which remained 'slowed' relative to CON. These data suggest that the hyperventilation manoeuvre itself (i.e. independent of induced hypocapnic alkalosis) may contribute to the slower V(O₂p) kinetics observed during HYPO.Keywords:
Hypocapnia
Normocapnia
Respiratory alkalosis
Alkalosis
Recently one of us (G. H. M.) reviewed the factors involved in the regulation of acid-base balance and pointed out the necessity of actual determination of the blood pH for correct differentiation of respiratory and metabolic acidosis and alkalosis.1 Breathing in excess of the physiological requirements removes excessive quantities of carbon dioxide from the blood and tends to produce alkalosis. Hyperventilation may be severe enough to overcome the compensatory mechanisms, and the pH of the blood then rises above the accepted upper limit of normal (7.45). Symptoms that result include tingling of the fingers and toes, numbness of the face followed by carpopedal spasm and ultimately by generalized spasms, convulsions, delirium and disorientation. Alkalosis due to hyperventilation may be induced in a number of ways as outlined by Peters,2and Cantarow and Trumper3: acute hyperventilation, which occurs in unstable persons under sudden emotional stress; fever hyperventilation, which
Respiratory alkalosis
Alkalosis
Acid–base homeostasis
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Hyperventilation is defined as breathing in excess of the metabolic needs of the body, eliminating more carbon dioxide than is produced, and, consequently, resulting in respiratory alkalosis and an elevated blood pH. The traditional definition of hyperventilation syndrome describes "a syndrome, characterized by a variety of somatic symptoms induced by physiologically inappropriate hyperventilation and usually reproduced by voluntary hyperventilation". The spectrum of symptoms ascribed to hyperventilation syndrome is extremely broad, aspecific and varying. They stem from virtually every tract, and can be caused by physiological mechanisms such as low Pa,CO2, or the increased sympathetic adrenergic tone. Psychological mechanisms also contribute to the symptomatology, or even generate some of the symptoms. Taking the traditional definition of hyperventilation syndrome as a starting point, there should be three elements to the diagnostic criterion: 1) the patient should hyperventilate and have low Pa,CO2, 2) somatic diseases causing hyperventilation should have been excluded, and 3) the patient should have a number of complaints which are, or have been, related to the hypocapnia. Recent studies have questioned the tight relationship between hypocapnia and complaints. However, the latter can be maintained and/or elicited when situations in the absence of hypocapnia in which the first hyperventilation and hypocapnia was present recur. Thus, the main approach to diagnosis is the detection of signs of (possible) dysregulation of breathing leading to hypocapnia. The therapeutic approach to hyperventilation syndrome has several stages and/or degrees of intervention: psychological counselling, physiotherapy and relaxation, and finally drug therapy. Depending on the severity of the problem, one or more therapeutic strategies can be chosen.
Hypocapnia
Hyperventilation syndrome
Respiratory alkalosis
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Normocapnia
Hypocapnia
Nitrous oxide
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Hypocapnia
Normocapnia
Arterial blood
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Hyperventilation may reverse increases in cerebral blood flow velocity caused by inhalation of nitrous oxide (N2O). This study sought to determine whether inhalation of 50% nitrous oxide after the induction of hyperventilation increases cerebral blood flow velocity as measured by transcranial Doppler ultrasonography. Seven volunteers breathed air/O2 through a modified Circle system at normocapnia followed by air/O2 with hyperventilation, and then N2O/O2 with hyperventilation. Expired gas concentrations were measured in the expiratory limb of the circuit distal to a one-way valve. Hyperventilation reduced end-tidal carbon dioxide from 38 ± 1mmHg to 26 ± 1mmHg. Hypocapnia was maintained during inhalation of N2O (EtCO2=28 ± 1mmHg). Mean cerebral blood flow velocity decreased 34% with hyperventilation (38 ± 4 cm/second versus 59 ± 9 cm/second, p < 0.05) and returned to baseline with the addition of nitrous oxide (58 ± 7 cm/second), despite persistent hypocapnia. The addition of nitrous oxide to the inspired gas mixture after induction of hypocapnia reversed reductions in cerebral blood flow velocity associated with hyperventilation. Potential benefits of induced hypocapnia in patients with intracranial pathology may be offset by the administration of N2O.
Hypocapnia
Normocapnia
Nitrous oxide
Transcranial Doppler
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Hypocapnia
Respiratory alkalosis
Alkalosis
Bicarbonate
pCO2
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The purpose of this study is to investigate the effects of hyperventilation upon spinal dorsal horn neuronal single-unit activities under nitrous oxide anesthesia.Eight decerebrated spinal cats with laminectomy were maintained with oxygen and pancuronium bromide. Following the control period of normocapnia, 50% nitrous oxide was administered for 30 minutes after a hypocapnia period of 20-25 mmHg for 20 minutes. The recoveries of activities followed with normocapnia and pure oxygen administration. The changes of spontaneous and evoked activities by the pinching were investigated every 5 minutes after control study.Inhalation of 50% nitrous oxide suppressed the WDR neuronal activities and with hyperventilation the suppressions significantly increased.These results were compatible with clinical reports on the effectiveness of hyperventilation as a maintenance method under N2O anesthesia.
Normocapnia
Hypocapnia
Nitrous oxide
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Pulmonary O2 uptake (V(O₂p)) and leg blood flow (LBF) kinetics were examined at the onset of moderate-intensity exercise, during hyperventilation with and without associated hypocapnic alkalosis. Seven male subjects (25 ± 6 years old; mean ± SD) performed alternate-leg knee-extension exercise from baseline to moderate-intensity exercise (80% of estimated lactate threshold) and completed four to six repetitions for each of the following three conditions: (i) control [CON; end-tidal partial pressure of CO2 (P(ET, CO₂)) ~40 mmHg], i.e. normal breathing with normal inspired CO2 (0.03%); (ii) hypocapnia (HYPO; P(ET, CO₂) ~20 mmHg), i.e. sustained hyperventilation with normal inspired CO2 (0.03%); and (iii) normocapnia (NORMO; P(ET, CO₂) ~40 mmHg), i.e. sustained hyperventilation with elevated inspired CO2 (~5%). The V(O₂p) was measured breath by breath using mass spectrometry and a volume turbine. Femoral artery mean blood velocity was measured by Doppler ultrasound, and LBF was calculated from femoral artery diameter and mean blood velocity. Phase 2 V(O₂p) kinetics (τV(O₂p)) was different (P < 0.05) amongst all three conditions (CON, 19 ± 7 s; HYPO, 43 ± 17 s; and NORMO, 30 ± 8 s), while LBF kinetics (τLBF) was slower (P < 0.05) in HYPO (31 ± 9 s) compared with both CON (19 ± 3 s) and NORMO (20 ± 6 s). Similar to previous findings, HYPO was associated with slower V(O₂p) and LBF kinetics compared with CON. In the present study, preventing the fall in end-tidal P(CO₂) (NORMO) restored LBF kinetics, but not V(O₂p) kinetics, which remained 'slowed' relative to CON. These data suggest that the hyperventilation manoeuvre itself (i.e. independent of induced hypocapnic alkalosis) may contribute to the slower V(O₂p) kinetics observed during HYPO.
Hypocapnia
Normocapnia
Respiratory alkalosis
Alkalosis
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Hypocapnia
Normocapnia
Capnography
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Hypocapnia
Respiratory alkalosis
Hypoxia
Alkalosis
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