Correlation of EtCO₂- and P(A-a)O₂-Based Dead Space Calculations in Mechanically Ventilated ICU Patients

Completed

• Conditions: Physiological Dead Space; Ventilation-Perfusion Mismatch; Mechanical Ventilation; Enghoff Correction

• Registration Number: NCT06947486
• Lead Sponsor: Karadeniz Technical University

Brief Summary

This study aims to evaluate two different methods for calculating physiological dead space in adult patients undergoing invasive mechanical ventilation in the intensive care unit (ICU). Physiological dead space refers to the portion of air that is ventilated but does not participate in gas exchange due to impaired perfusion or ventilation-perfusion mismatch.

Traditionally, dead space is calculated using the end-tidal carbon dioxide (EtCO₂) method, which estimates the difference between arterial and exhaled CO₂ values. However, this method may be influenced by circulatory failure or abnormal CO₂ distribution. An alternative method using the alveolar-arterial oxygen gradient \[P(A-a)O₂\] has been proposed, as it may provide a more stable measurement under critical conditions by relying on oxygenation efficiency rather than CO₂ elimination.

In this prospective observational study, patients receiving mechanical ventilation in a tertiary ICU will be monitored. Physiological dead space will be calculated using both the EtCO₂-based method and the P(A-a)O₂-based method. Various respiratory and clinical parameters, including arterial blood gases, ventilator settings, and severity scores, will be recorded. The correlation between the two methods will be assessed, and their relationship with ICU mortality will be analyzed.

The results of this study may help determine whether the P(A-a)O₂ method can be used as a reliable alternative for estimating dead space in ICU patients and whether it has prognostic value in predicting patient outcomes.

Detailed Description

Physiological dead space (VD/VT) is a key parameter in evaluating the efficiency of gas exchange in mechanically ventilated patients. It represents the fraction of each breath that does not participate in effective alveolar ventilation due to perfusion defects, shunt physiology, or mismatched ventilation-perfusion (V/Q) ratios. An elevated dead space fraction has been associated with poor clinical outcomes, especially in patients with acute respiratory failure or circulatory impairment.

The most commonly used method for estimating dead space in the intensive care setting is based on the Enghoff modification of the Bohr equation:

VD/VT = (PaCO₂ - EtCO₂) / PaCO₂

This approach utilizes the arterial carbon dioxide pressure (PaCO₂) and end-tidal carbon dioxide pressure (EtCO₂) to estimate the proportion of ventilation that does not contribute to CO₂ elimination. However, it assumes a relatively homogenous V/Q distribution and may lose accuracy in the presence of increased shunt, circulatory shock, or CO₂ transport abnormalities.

To improve on these limitations, the present study also incorporates the alveolar-arterial oxygen gradient \[P(A-a)O₂\] as an alternative method for estimating physiological dead space. The gradient is calculated as:

P(A-a)O₂ = PAO₂ - PaO₂, where PAO₂ = FiO₂ × (Patm - PH₂O) - (PaCO₂ / R)

The dead space ratio can then be estimated by a similar structure:

VD/VT = (PAO₂ - PaO₂) / PAO₂

The P(A-a)O₂-based method may offer more robust estimations under critically ill conditions, particularly in cases with oxygenation defects or hemodynamic compromise, as it is less affected by variations in CO₂ distribution or metabolism.

In addition to Enghoff and oxygen-based approaches, this study also evaluates the Kuwabara modification, which adjusts for venous admixture and attempts to more accurately reflect the effective alveolar ventilation in the presence of shunt physiology. Kuwabara and Duncalf introduced a correction to the dead space formula to account for anatomical and functional shunts, reducing potential overestimation caused by disproportionate alveolar ventilation:

Corrected VD/VT = \[(PaCO₂ - EtCO₂) / PaCO₂\] × α

Where α represents a correction factor that adjusts for venous admixture and other circulatory influences.

This prospective observational study will include adult patients undergoing invasive mechanical ventilation in a tertiary ICU. Participants will be evaluated at multiple time points using volumetric capnography, arterial and venous blood gases, and ventilator-derived parameters. Physiological dead space will be calculated in parallel using:

Enghoff's method

P(A-a)O₂-based oxygenation gradients

Kuwabara correction for venous admixture

Daily clinical scores (SOFA, APACHE II), ventilator mechanics (PEEP, tidal volume, FiO₂, plateau pressure, driving pressure), and gas exchange variables (PaCO₂, PaO₂/FiO₂, VCO₂, VO₂) will also be recorded.

The study aims to assess:

The correlation between the EtCO₂- and P(A-a)O₂-based dead space methods

The influence of shunt and hemodynamic variables on dead space estimation

The prognostic relevance of each method in relation to ICU mortality

This study seeks to contribute to the optimization of dead space measurement in the ICU by evaluating alternative, potentially more reliable physiologic methods. It also aims to inform future clinical practice by identifying the most accurate and clinically useful dead space assessment tools in the context of severe critical illness.

Study Timeline

• Study Start: 2025-01-05
• Status Verified: 2025-04
• Primary Completion: 2025-04-10
• Study Completion: 2025-04-18
• Study First Submitted: 2025-04-20
• Study First Submitted QC: 2025-04-20
• Last Update Submitted: 2025-04-20
• Study First Posted: 2025-04-27
• Last Update Posted: 2025-04-27

Recruitment & Eligibility

• Status: COMPLETED
• Sex: All
• Target Recruitment: 41

Inclusion Criteria

• Age ≥ 18 years
• Admission to the intensive care unit (ICU)
• Receiving invasive mechanical ventilation
• Expected ICU stay ≥ 24 hours
• Availability of both arterial blood gas and volumetric capnography measurements
• Central venous cathater for central venous blood analyses
• Informed consent obtained from legal representative

Exclusion Criteria

• Refusal of participation by the patient or legal surrogate
• Hemoglobin < 7 g/dL
• PaCO₂ > 70 mmHg
• Lactate > 4 mmol/L
• Capillary refill time > 3 seconds
• Mean arterial pressure (MAP) < 65 mmHg
• Mottling score ≥ 2
• PaCO₂ - PcCO₂ gradient > 8 mmHg
• pH < 7.20
• Body temperature > 38°C
• BMI > 40 kg/m²
• VCO₂ > 4 mL/kg/min
• Technical limitations preventing accurate capnographic monitoring
• Patients who are extubated, transferred, or deceased within the first 24 hours

Study & Design

• Study Type: OBSERVATIONAL
• Study Design: Not specified

Primary Outcome Measures

Name	Time	Method
Correlation between EtCO₂- and P(A-a)O₂-based dead space calculations	Within the first 72 hours of ICU admission	Description: Pearson or Spearman correlation coefficient calculated between dead space values obtained from EtCO₂ (Enghoff modification) and P(A-a)O₂-based gradient methods in mechanically ventilated ICU patients.

Secondary Outcome Measures

Name	Time	Method
Association of each dead space method with ICU mortality	From ICU admission until ICU discharge or death	Evaluation of whether EtCO₂- and P(A-a)O₂-derived dead space values are independently associated with ICU mortality.
Agreement between EtCO₂- and P(A-a)O₂-based dead space estimates	Within first 3 days of ICU stay	Bland-Altman and bias analysis to evaluate agreement between the two measurement methods.
Relationship between dead space values and gas exchange/ perfusion variables	Daily for up to 72 hours	Correlation between VD/VT and parameters such as PaO₂/FiO₂, lactate, MAP, and mottling score.

Trial Locations

Locations (1)

Karadeniz Technical University Faculty of Medicine, Department of Chest Diseases, Intensive Care Unit; 🇹🇷 Trabzon, Turkey