
The relationship between minute ventilation and end tidal CO2 in intubated and spontaneously breathing patients undergoing procedural sedation
Author(s) -
Jaideep H. Mehta,
George W. Williams,
Brian C. Harvey,
Navneet Grewal,
Edward George
Publication year - 2017
Publication title -
plos one
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.99
H-Index - 332
ISSN - 1932-6203
DOI - 10.1371/journal.pone.0180187
Subject(s) - medicine , anesthesia , capnography , sedation , tidal volume , respiratory minute volume , ventilation (architecture) , respiratory rate , propofol , mechanical ventilation , respiratory monitoring , impedance cardiography , respiratory system , heart rate , blood pressure , stroke volume , mechanical engineering , engineering
Background Monitoring respiratory status using end tidal CO 2 (EtCO 2 ), which reliably reflects arterial PaCO 2 in intubated patients under general anesthesia, has often proven both inaccurate and inadequate when monitoring non-intubated and spontaneously breathing patients. This is particularly important in patients undergoing procedural sedation (e.g., endoscopy, colonoscopy). This can be undertaken in the operating theater, but is also often delivered outside the operating room by non-anesthesia providers. In this study we evaluated the ability for conventional EtCO 2 monitoring to reflect changes in ventilation in non-intubated surgical patients undergoing monitored anesthesia care and compared and contrasted these findings to both intubated patients under general anesthesia and spontaneously breathing volunteers. Methods Minute Ventilation (MV), tidal volume (TV), and respiratory rate (RR) were continuously collected from an impedance-based Respiratory Volume Monitor (RVM) simultaneously with capnography data in 160 patients from three patient groups: non-intubated surgical patients managed using spinal anesthesia and Procedural Sedation (n = 58); intubated surgical patients under General Anesthesia (n = 54); and spontaneously breathing Awake Volunteers (n = 48). EtCO 2 instrument sensitivity was calculated for each patient as the slope of a Deming regression between corresponding measurements of EtCO 2 and MV and expressed as angle from the x-axis (θ). All data are presented as mean ± SD unless otherwise indicated. Results While, as expected, EtCO 2 and MV measurements were negatively correlated in most patients, we found gross systematic differences across the three cohorts. In the General Anesthesia patients, small changes in MV resulted in large changes in EtCO 2 (high sensitivity, θ = -83.6 ± 9.9°). In contrast, in the Awake Volunteers patients, large changes in MV resulted in insignificant changes in EtCO 2 (low sensitivity, θ = -24.7 ± 19.7°, p < 0.0001 vs General Anesthesia). In the Procedural Sedation patients, EtCO 2 sensitivity showed a bimodal distribution, with an approximately even split between patients showing high EtCO 2 instrument sensitivity, similar to those under General Anesthesia, and patients with low EtCO 2 instrument sensitivity, similar to the Awake Volunteers. Conclusions When monitoring non-intubated patients undergoing procedural sedation, EtCO 2 often provides inadequate instrument sensitivity when detecting changes in ventilation. This suggests that augmenting standard patient care with EtCO 2 monitoring is a less than optimal solution for detecting changes in respiratory status in non-intubated patients. Instead, adding direct monitoring of MV with an RVM may be preferable for continuous assessment of adequacy of ventilation in non-intubated patients.