Utility of monitoring capnography, pulse oximetry, and vital signs in the detection of airway mishaps: A hyperoxemic animal model

This study was undertaken to determine the time interval for changes in end-tidal CO 2, oxygen saturation (Sao 2), heart rate (HR), and blood pressure (BP) in response to an acute airway obstruction or hypopharyngeal extubation in a hyperoxemic model. Complete and partial airway obstructions were si...

Full description

Saved in:
Bibliographic Details
Published in:The American journal of emergency medicine 1998-07, Vol.16 (4), p.350-352
Main Authors: Poirier, Michael P, Gonzalez Del-Rey, Javier A, McAneney, Constance M, Digiulio, Gregg A
Format: Article
Language:English
Subjects:
Airway Obstruction - diagnosis
Airway Obstruction - etiology
Airway Obstruction - metabolism
Airway Obstruction - physiopathology
Anesthesia. Intensive care medicine. Transfusions. Cell therapy and gene therapy
Animals
Biological and medical sciences
Blood Pressure
Capnography - standards
Capnometry
Disease Models, Animal
Emergency and intensive care: techniques, logistics
endotracheal tube
Equipment Failure
Heart Rate
hyperoxemic
Hyperoxia - etiology
Intensive care medicine
Intubation, Intratracheal - adverse effects
Medical sciences
Monitoring
Monitoring, Physiologic - methods
Monitoring, Physiologic - standards
oximetry
Oximetry - standards
Oxygen Inhalation Therapy
Sensitivity and Specificity
Swine
Swine, Miniature
Time Factors
transport
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:This study was undertaken to determine the time interval for changes in end-tidal CO 2, oxygen saturation (Sao 2), heart rate (HR), and blood pressure (BP) in response to an acute airway obstruction or hypopharyngeal extubation in a hyperoxemic model. Complete and partial airway obstructions were simulated with complete and partial cross-clamping of an endotracheal (ET) tube in five anesthetized, nonparalyzed, mechanically ventilated Yorkshire minipigs with initial Pao 2 of >400 mm Hg. Placement of the ET tube into the hypopharynx was performed to simulate accidental extubation. Both sidestream (SS) and mainstream (MS) capnography were used. Continuous pulse oximetry monitored Sao 2, femoral arterial catheter monitored systolic BP, and electrocardiograph monitored HR. The time intervals for the capnograph wave to flatten and for the monitor to display zero were recorded after each airway alteration. The time interval to a change in the initial HR of 10 beats/min, a change of initial systolic BP of 10 mm Hg, and a change of initial Sao 2 of 5% were recorded. Experiments were carried out for 180 seconds, and 25 trials were performed. HR, systolic BP, and Sao 2 did not change for the 180-second duration of the trials. Complete obstruction produced a flattening of the SS and MS waveform in 8 ± 2 seconds and 6 ± 2 seconds, respectively. The SS and MS monitors displayed zero in 19 ± 1 seconds and 68 ± 7 seconds, respectively. Partial obstruction did not produce flattening of the wave or a monitor displaying zero. Hypopharyngeal extubation produced a flattening of the SS and MS waveform in 7 ± 1 seconds and 7 ± 2 seconds, respectively. The SS and MS monitors displayed zero in 18 ± 3 seconds and 76 ± 16 seconds, respectively. Continuous end-tidal CO 2 capnography detects acute airway obstruction and hypopharyngeal extubation more rapidly than does pulse oximetry or vital sign monitoring in a hyperoxemic porcine model.
ISSN:0735-6757
1532-8171
DOI:10.1016/S0735-6757(98)90125-5