Effects of PERMISSive Lung-protective Ventilation on Outcome in Critically Ill Invasively Ventilated Patients

Summary

RATIONALE Lung-protective ventilation using a lower respiratory rate (RR) is an appealing strategy to reduce ventilation intensity, which may require permissive hypercapnia. However, the feasibility and safety of this so-called 'permissive lung-protective ventilation' must be investigated, before conducting a large randomized clinical trial to evaluate its effectiveness on patient-centered outcomes.

OBJECTIVE To study the feasibility and safety of permissive lung-protective ventilation in adult critically ill patients receiving invasive ventilation for acute hypoxemic respiratory failure, and to inform the design of a future randomized clinical trial in this patient population.

HYPOTHESIS Permissive lung-protective ventilation is a feasible and safe ventilation strategy.

STUDY DESIGN Multicenter, randomized clinical pilot trial. STUDY POPULATION Critically ill patients, aged \> 18 years, intubated for acute hypoxemic respiratory failure, and expected to receive ventilation for \> 24 hours.

METHODS Patients are randomized to permissive lung-protective ventilation wherein RR is stepwise reduced, or to conventional lung-protective ventilation.

OUTCOME MEASURES The primary endpoint is feasibility, assessed by the difference in respiratory rate (RR) between the two groups, from the start of mechanical ventilation until first extubation. Secondary endpoints include protocol compliance and feasibility of collecting data, and safety, assessed by the occurrence of unacceptable hypercapnia and hypoxemia and the incidence of ventilator-associated complications SAMPLE SIZE To estimate the appropriate sample size for this pilot study, we considered the primary feasibility endpoint of detecting a difference in the respiratory rate (RR). Assuming an expected mean difference in RR of 7.5, based on previous studies \[1, 2\], with an SD of 10, a power of 90% and an alpha of 0.05, with a drop-out rate estimated at 10%, a two-tailed t-test was used. The required sample size is 84 patients (42 patients per group).

NATURE AND EXTENT OF THE BURDEN AND RISKS ASSOCIATED WITH PARTICIPATION, BENEFIT AND GROUP RELATEDNESS Ventilation with a lower RR may require permissive hypercapnia, which, when kept within safe limits, is safe. In current daily practice, there is no guidance in setting RR; consequently, RR varies widely across patients and is often set high. This pilot study compares two forms of lung-protective ventilation, both considered standard care in current ICU practice. The control group receives conventional ventilation with low tidal volumes and high RR to maintain normal PaCO₂ and pH. The intervention group, permissive ventilation, uses a lower RR to reduce mechanical power, accepting mild hypercapnia and acidosis. Permissive ventilation is most often reserved for patients with severe lung conditions, where ventilator settings are more complex and ventilation intensity is high. In these patients, permissive ventilation is considered safe, and may even be beneficial. We aim to evaluate this strategy more broadly in critically ill patients. The collection of demographic, ventilation and outcome data causes no harm to patients. Blood is drawn for arterial blood gas analysis, but this is also part of standard care.

Conditions

• Mechanical Ventilation
• Intensive Care (ICU)

Interventions

OTHER

Permissive lung-protective ventilation

The goal is to achieve the lowest possible respiratory rate (RR) according to a guideline in which the target RR is estimated by combining the baseline RR with the results of arterial blood gas analysis (ABG), determined by the highest acceptable partial pressure of carbon dioxide (PaCO2) of ≤ 8.5 kPa (64 mmHg) but limited by the lowest acceptable arterial pH (pHa) of \> 7.20. The RR is gradually decreased, in steps of 2 breaths every 10 minutes, based on continuous end-tidal CO2 monitoring. To ensure that the pHa does not fall below 7.20, following randomization, ABGs are repeated every hour until the target RR is reached, for at least 6 hours. Thereafter, blood gas analyses are repeated at least every 8 hours (at the start of every nursing shift). Down-titration of RR stops at a rate of 4 breaths per minute. This approach continues until the switch to spontaneous breathing. Of note, when the pHa is \> 7.50, this must first be decreased to ≤ 7.50 based on local protocol.

OTHER

Conventional lung-protective ventilation

Following randomization, which should happen within 1 hour after start of ventilation in the ICU, the RR is set according to standard of care, based on continuous end-tidal CO2 monitoring, to target a normal PaCO2 (4.7-6.4 kPa or 35-48 mmHg) combined with a pHa within the range of 7.35 to 7.45. Following randomization, blood gas analyses are repeated every hour for at least 6 hours, and thereafter at least every 8 hours (at the start of every nursing shift). This approach continues until the weaning phase.

Sponsors & Collaborators

• Reinier de Graaf Groep

  lead OTHER

Principal Investigators

• Laura Buiteman-Kruizinga, RN, PhD · Reinier de Graaf Groep

• Marcus J. Schultz, MD, PhD · Amsterdam UMC

Study Design

Allocation

RANDOMIZED

Purpose

TREATMENT

Masking

SINGLE

Model

PARALLEL

Eligibility

Min Age

18 Years

Sex

ALL

Healthy Volunteers

No

Timeline & Regulatory

Start

2025-08-31

Primary Completion

2026-07-31

Completion

2026-08-31

Countries

• Netherlands
• Spain

Study Locations