Prospective targeting and control of end‐tidal CO2 and O2 concentrations

Current methods of forcing end‐tidal PCO2 (PETCO2) and PO2 (PETO2) rely on breath‐by‐breath adjustment of inspired gas concentrations using feedback loop algorithms. Such servo‐control mechanisms are complex because they have to anticipate and compensate for the respiratory response to a given inspiratory gas concentration on a breath‐by‐breath basis. In this paper, we introduce a low gas flow method to prospectively target and control PETCO2 and PETO2 independent of each other and of minute ventilation in spontaneously breathing humans. We used the method to change PETCO2 from control (40 mmHg for PETCO2 and 100 mmHg for PETO2) to two target PETCO2 values (45 and 50 mmHg) at iso‐oxia (100 mmHg), PETO2 to two target values (200 and 300 mmHg) at normocapnia (40 mmHg), and PETCO2 with PETO2 simultaneously to the same targets (45 with 200 mmHg and 50 with 300 mmHg). After each targeted value, PETCO2 and PETO2 were returned to control values. Each state was maintained for 30 s. The average difference between target and measured values for PETCO2 was ± 1 mmHg, and for PETO2 was ± 4 mmHg. PETCO2 varied by ± 1 mmHg and PETO2 by ± 5.6 mmHg (s.d.) over the 30 s stages. This degree of control was obtained despite considerable variability in minute ventilation between subjects (± 7.6 l min−1). We conclude that targeted end‐tidal gas concentrations can be attained in spontaneously breathing subjects using this prospective, feed‐forward, low gas flow system.

[1]  D. O'Connor,et al.  Chamber for controlling end-tidal gas tensions over sustained periods in humans. , 1995, Journal of applied physiology.

[2]  M. Poulin,et al.  Cerebral blood flow sensitivity to CO2 measured with steady-state and Read's rebreathing methods , 2003, Respiratory Physiology & Neurobiology.

[3]  D. Smith,et al.  Servo control of end-tidal CO2 in paralyzed animals. , 1978, Journal of applied physiology: respiratory, environmental and exercise physiology.

[4]  J. Bussink,et al.  ARCON: a novel biology-based approach in radiotherapy. , 2002, The Lancet. Oncology.

[5]  G. Volgyesi,et al.  A simple breathing circuit minimizing changes in alveolar ventilation during hyperpnoea. , 1998, The European respiratory journal.

[6]  J. Patterson,et al.  Role of hypocapnia in the circulatory responses to acute hypoxia in man. , 1966, Journal of applied physiology.

[7]  M. Poulin,et al.  Fast and slow components of cerebral blood flow response to step decreases in end-tidal PCO 2 in humans , 1998 .

[8]  T. Floyd,et al.  Independent cerebral vasoconstrictive effects of hyperoxia and accompanying arterial hypocapnia at 1 ATA. , 2003, Journal of applied physiology.

[9]  G D Swanson,et al.  A fast gas-mixing system for breath-to-breath respiratory control studies. , 1982, Journal of applied physiology: respiratory, environmental and exercise physiology.

[10]  J. Laffey,et al.  Carbon dioxide and the critically ill—too little of a good thing? , 1999, The Lancet.

[11]  A Hauge,et al.  Changes in human cerebral blood flow due to step changes in PAO2 and PACO2. , 1987, Acta physiologica Scandinavica.

[12]  J. Dempsey,et al.  Cerebrovascular response to carbon dioxide in patients with congestive heart failure. , 2005, American journal of respiratory and critical care medicine.

[13]  J. Flanagan,et al.  The impact of hypercapnia on retinal capillary blood flow assessed by scanning laser Doppler flowmetry. , 2005, Microvascular research.

[14]  M. Poulin,et al.  Fast and slow components of cerebral blood flow response to step decreases in end-tidal PCO2 in humans. , 1998, Journal of applied physiology.

[15]  W. O. Friesen,et al.  Hypoxic ventilatory drive in normal man. , 1970, The Journal of clinical investigation.

[16]  John B. West,et al.  Respiratory Physiology - the Essentials , 1979 .

[17]  L. Moore,et al.  Variable inhibition by falling CO2 of hypoxic ventilatory response in humans. , 1984, Journal of applied physiology: respiratory, environmental and exercise physiology.

[18]  J. Nunn,et al.  Applied respiratory physiology with special reference to anaesthesia , 1969 .

[19]  J. Severinghaus,et al.  Augmented hypoxic ventilatory response in men at altitude. , 1992, Journal of applied physiology.

[20]  R B Banzett,et al.  Simple contrivance "clamps" end-tidal PCO(2) and PO(2) despite rapid changes in ventilation. , 2000, Journal of applied physiology.

[21]  G D Swanson,et al.  A prediction-correction scheme for forcing alveolar gases along certain time courses. , 1982, Journal of applied physiology: respiratory, environmental and exercise physiology.

[22]  N. Cherniack,et al.  Oxygen and carbon dioxide gas stores of the body. , 1970, Physiological reviews.

[23]  David J Mikulis,et al.  Preoperative and postoperative mapping of cerebrovascular reactivity in moyamoya disease by using blood oxygen level-dependent magnetic resonance imaging. , 2005, Journal of neurosurgery.

[24]  S Iscoe,et al.  Precise Control of End-tidal Carbon Dioxide Levels Using Sequential Rebreathing Circuits , 2005, Anaesthesia and intensive care.

[25]  M. Poulin,et al.  Changes in Cerebral Blood Flow During and After 48 H of Both Isocapnic and Poikilocapnic Hypoxia in Humans , 2002, Experimental physiology.

[26]  D. Leith,et al.  Ventilatory muscle training and the oxygen cost of sustained hyperpnea. , 1978, Journal of applied physiology: respiratory, environmental and exercise physiology.

[27]  R. J. Harrison,et al.  The Lung: Clinical Physiology and Pulmonary Function Tests , 1956 .

[28]  Kojiro Ide,et al.  Relationship between middle cerebral artery blood velocity and end-tidal PCO2 in the hypocapnic-hypercapnic range in humans. , 2003, Journal of applied physiology.

[29]  G. Volgyesi,et al.  MRI mapping of cerebrovascular reactivity using square wave changes in end‐tidal PCO2 , 2001, Magnetic resonance in medicine.

[30]  M. Poulin,et al.  Dynamics of the cerebral blood flow response to step changes in end-tidal PCO2 and PO2 in humans. , 1996, Journal of applied physiology.