The effect of partial upper-airway bypass on subglottic pressure during acute lung injury in sheep

M. H. Kollef, Michael Mccormack, R. E. Banks

Research output: Contribution to journalArticle

Abstract

Background: upper-airway function is thought to influence gas exchange and lung volume through an expiratory braking mechanism producing increased subglottic pressures. We designed an experiment to examine the effect of partial upper-airway bypass on the development of subglottic pressure during acute lung injury (ALI). Materials and methods: six healthy adult domestic sheep underwent surgical placement of a tracheal Kistner button in the upper trachea and carotid transposition for arterial blood access. On the following day, baseline airway-pressure tracings were obtained at the Kistner button, and respiratory airflow tracings were obtained at the mouth. All measurements and recordings were initially made with the Kistner buttons closed to atmosphere, allowing respiration only across the upper airway, and then were repeated with the Kistner buttons open, allowing partial respiratory bypass of the upper airway. Twenty-four hours following the baseline recordings, an intravenous infusion of oleic acid (0.08 mL/kg) was administered to produce ALI. On the following day, the recordings were repeated and arterial blood gas samples were obtained. Results: subglottic pressures at baseline with the Kistner buttons closed (3.5 cm H2O [0.34 kPa]) were significantly larger than when the Kistner buttons were open, (1.4 cm H2O [0.14 kPa], p < 0.0001). The respiratory rates, inspiratory times (t(i)), expiratory times (t(e)), and the t(i)-to-t(e) ratio (I:E) were unchanged with the Kistner buttons open to atmosphere. With ALI, subglottic pressure was significantly increased (p > 0.0001), compared to baseline (12.3 cm H2O [1.21 kPa] vs cm H2O [0.34 kPa], respectively). Other variables demonstrated a decrease in the t(i) (p < 0.001) and a decrease in the I:E (p < 0.0001) compared to baseline measurements. No significant difference existed in t(e) or the respiratory rates. Opening of the Kistner buttons during acute lung injury produced a significant decrease in subglottic pressures (p < 0.0001) and t(e) (p = 0.0031), whereas the t(i) and I:E significantly increased with this maneuver (p = 0.0002 and p < 0.0001, respectively). The partial pressures of oxygen were found to be significantly greater (p = 0.0401) with the Kistner buttons closed to atmosphere (64.3 torr [8.58 kPa]) than when they were open (53.5 torr [7.13 kPa]), during ALI. Conclusions: our results suggest that (1) partial bypass of the upper airway may be associated with a decrease in the development of subglottic pressures, and (2) respiratory timing and pulmonary gas exchange are influenced by the upper airway during ALI.

Original languageEnglish (US)
Pages (from-to)1166-1174
Number of pages9
JournalRespiratory Care
Volume37
Issue number10
StatePublished - Jan 1 1992
Externally publishedYes

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Acute Lung Injury
Sheep
Pressure
Atmosphere
Gases
Domestic Sheep
Pulmonary Gas Exchange
Pulmonary Ventilation
Partial Pressure
Oleic Acid
Respiratory Rate
Trachea
Intravenous Infusions
Mouth
Respiration
Oxygen
Lung

All Science Journal Classification (ASJC) codes

  • Medicine(all)

Cite this

The effect of partial upper-airway bypass on subglottic pressure during acute lung injury in sheep. / Kollef, M. H.; Mccormack, Michael; Banks, R. E.

In: Respiratory Care, Vol. 37, No. 10, 01.01.1992, p. 1166-1174.

Research output: Contribution to journalArticle

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abstract = "Background: upper-airway function is thought to influence gas exchange and lung volume through an expiratory braking mechanism producing increased subglottic pressures. We designed an experiment to examine the effect of partial upper-airway bypass on the development of subglottic pressure during acute lung injury (ALI). Materials and methods: six healthy adult domestic sheep underwent surgical placement of a tracheal Kistner button in the upper trachea and carotid transposition for arterial blood access. On the following day, baseline airway-pressure tracings were obtained at the Kistner button, and respiratory airflow tracings were obtained at the mouth. All measurements and recordings were initially made with the Kistner buttons closed to atmosphere, allowing respiration only across the upper airway, and then were repeated with the Kistner buttons open, allowing partial respiratory bypass of the upper airway. Twenty-four hours following the baseline recordings, an intravenous infusion of oleic acid (0.08 mL/kg) was administered to produce ALI. On the following day, the recordings were repeated and arterial blood gas samples were obtained. Results: subglottic pressures at baseline with the Kistner buttons closed (3.5 cm H2O [0.34 kPa]) were significantly larger than when the Kistner buttons were open, (1.4 cm H2O [0.14 kPa], p < 0.0001). The respiratory rates, inspiratory times (t(i)), expiratory times (t(e)), and the t(i)-to-t(e) ratio (I:E) were unchanged with the Kistner buttons open to atmosphere. With ALI, subglottic pressure was significantly increased (p > 0.0001), compared to baseline (12.3 cm H2O [1.21 kPa] vs cm H2O [0.34 kPa], respectively). Other variables demonstrated a decrease in the t(i) (p < 0.001) and a decrease in the I:E (p < 0.0001) compared to baseline measurements. No significant difference existed in t(e) or the respiratory rates. Opening of the Kistner buttons during acute lung injury produced a significant decrease in subglottic pressures (p < 0.0001) and t(e) (p = 0.0031), whereas the t(i) and I:E significantly increased with this maneuver (p = 0.0002 and p < 0.0001, respectively). The partial pressures of oxygen were found to be significantly greater (p = 0.0401) with the Kistner buttons closed to atmosphere (64.3 torr [8.58 kPa]) than when they were open (53.5 torr [7.13 kPa]), during ALI. Conclusions: our results suggest that (1) partial bypass of the upper airway may be associated with a decrease in the development of subglottic pressures, and (2) respiratory timing and pulmonary gas exchange are influenced by the upper airway during ALI.",
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N2 - Background: upper-airway function is thought to influence gas exchange and lung volume through an expiratory braking mechanism producing increased subglottic pressures. We designed an experiment to examine the effect of partial upper-airway bypass on the development of subglottic pressure during acute lung injury (ALI). Materials and methods: six healthy adult domestic sheep underwent surgical placement of a tracheal Kistner button in the upper trachea and carotid transposition for arterial blood access. On the following day, baseline airway-pressure tracings were obtained at the Kistner button, and respiratory airflow tracings were obtained at the mouth. All measurements and recordings were initially made with the Kistner buttons closed to atmosphere, allowing respiration only across the upper airway, and then were repeated with the Kistner buttons open, allowing partial respiratory bypass of the upper airway. Twenty-four hours following the baseline recordings, an intravenous infusion of oleic acid (0.08 mL/kg) was administered to produce ALI. On the following day, the recordings were repeated and arterial blood gas samples were obtained. Results: subglottic pressures at baseline with the Kistner buttons closed (3.5 cm H2O [0.34 kPa]) were significantly larger than when the Kistner buttons were open, (1.4 cm H2O [0.14 kPa], p < 0.0001). The respiratory rates, inspiratory times (t(i)), expiratory times (t(e)), and the t(i)-to-t(e) ratio (I:E) were unchanged with the Kistner buttons open to atmosphere. With ALI, subglottic pressure was significantly increased (p > 0.0001), compared to baseline (12.3 cm H2O [1.21 kPa] vs cm H2O [0.34 kPa], respectively). Other variables demonstrated a decrease in the t(i) (p < 0.001) and a decrease in the I:E (p < 0.0001) compared to baseline measurements. No significant difference existed in t(e) or the respiratory rates. Opening of the Kistner buttons during acute lung injury produced a significant decrease in subglottic pressures (p < 0.0001) and t(e) (p = 0.0031), whereas the t(i) and I:E significantly increased with this maneuver (p = 0.0002 and p < 0.0001, respectively). The partial pressures of oxygen were found to be significantly greater (p = 0.0401) with the Kistner buttons closed to atmosphere (64.3 torr [8.58 kPa]) than when they were open (53.5 torr [7.13 kPa]), during ALI. Conclusions: our results suggest that (1) partial bypass of the upper airway may be associated with a decrease in the development of subglottic pressures, and (2) respiratory timing and pulmonary gas exchange are influenced by the upper airway during ALI.

AB - Background: upper-airway function is thought to influence gas exchange and lung volume through an expiratory braking mechanism producing increased subglottic pressures. We designed an experiment to examine the effect of partial upper-airway bypass on the development of subglottic pressure during acute lung injury (ALI). Materials and methods: six healthy adult domestic sheep underwent surgical placement of a tracheal Kistner button in the upper trachea and carotid transposition for arterial blood access. On the following day, baseline airway-pressure tracings were obtained at the Kistner button, and respiratory airflow tracings were obtained at the mouth. All measurements and recordings were initially made with the Kistner buttons closed to atmosphere, allowing respiration only across the upper airway, and then were repeated with the Kistner buttons open, allowing partial respiratory bypass of the upper airway. Twenty-four hours following the baseline recordings, an intravenous infusion of oleic acid (0.08 mL/kg) was administered to produce ALI. On the following day, the recordings were repeated and arterial blood gas samples were obtained. Results: subglottic pressures at baseline with the Kistner buttons closed (3.5 cm H2O [0.34 kPa]) were significantly larger than when the Kistner buttons were open, (1.4 cm H2O [0.14 kPa], p < 0.0001). The respiratory rates, inspiratory times (t(i)), expiratory times (t(e)), and the t(i)-to-t(e) ratio (I:E) were unchanged with the Kistner buttons open to atmosphere. With ALI, subglottic pressure was significantly increased (p > 0.0001), compared to baseline (12.3 cm H2O [1.21 kPa] vs cm H2O [0.34 kPa], respectively). Other variables demonstrated a decrease in the t(i) (p < 0.001) and a decrease in the I:E (p < 0.0001) compared to baseline measurements. No significant difference existed in t(e) or the respiratory rates. Opening of the Kistner buttons during acute lung injury produced a significant decrease in subglottic pressures (p < 0.0001) and t(e) (p = 0.0031), whereas the t(i) and I:E significantly increased with this maneuver (p = 0.0002 and p < 0.0001, respectively). The partial pressures of oxygen were found to be significantly greater (p = 0.0401) with the Kistner buttons closed to atmosphere (64.3 torr [8.58 kPa]) than when they were open (53.5 torr [7.13 kPa]), during ALI. Conclusions: our results suggest that (1) partial bypass of the upper airway may be associated with a decrease in the development of subglottic pressures, and (2) respiratory timing and pulmonary gas exchange are influenced by the upper airway during ALI.

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