FCV Vs VCV in Obstructive and Asthmatic Patients

Study Results

Results pending

The study team has not published outcome measurements, participant flow, or safety data for this trial yet. Check back later for updates.

Basic Information

Get a concise snapshot of the trial, including recruitment status, study phase, enrollment targets, and key timeline milestones.

Recruitment Status

RECRUITING

Clinical Phase

NA

Total Enrollment

10 participants

Study Classification

INTERVENTIONAL

Study Start Date

2024-10-31

Study Completion Date

2027-10-31

Brief Summary

Review the sponsor-provided synopsis that highlights what the study is about and why it is being conducted.

The goal of this physiological pilot study with a randomized crossover design is to study the effect of Flow-controlled ventilation (FCV) on the minute volume compared to Volume-controlled ventilation (VCV) in intubated patients with an exacerbation of their asthma or COPD.

Our hypothesis is that FCV will results in a lower minute volume compared to VCV in this patient category.

Patients will be randomized between two ventilation sequences, namely 90 minutes of FCV followed by 90 minutes of VCV or vice versa.

Related Clinical Trials

Explore similar clinical trials based on study characteristics and research focus.

Flow Controlled Ventilation (FCV) With the Evone Ventilator and Tritube Versus Volume Controlled Ventilation (VCV)

NCT03873233

Pulmonary Ventilation

COMPLETED PHASE3

The Effect of NOn-invasive Respiratory Support on outcoMe and Its Risks in SARS-COV-2-related Hypoxemic Respiratory Failure

NCT06757166

Target Trial Emulation, Invasive Mechanical Ventilation

RECRUITING

To Assess the Effectiveness of Three Distinct Mechanical Assisted Sputum Evacuation Apparatuses in the Treatment of Patients With Mechanical Ventilation-induced Atelectasis

NCT06631716

Mechanical Ventilation Atelectasis

NOT_YET_RECRUITING

Flow-controlled Ventilation (FCV) in Moderate Acute Respiratory Distress Syndrome (ARDS) Due to COVID-19

NCT04894214

COVID-19 Acute Respiratory Distress Syndrome Respiration, Artificial

COMPLETED

PROtective Ventilation With FLOW-Controlled Ventilation

NCT06703814

Postoperative Pulmonary Complications (PPCs) Feasibility Studies Pilot Study

RECRUITING NA

Detailed Description

Dive into the extended narrative that explains the scientific background, objectives, and procedures in greater depth.

Rationale: Patients with an exacerbation of asthma or chronic obstructive pulmonary disease (COPD) requiring controlled mechanical ventilation (CMV) on the intensive care unit (ICU) have a mortality rate between 10 and 20%. This mortality rate is largely explained by major complications associated with mechanical ventilation e.g., pneumothorax, cardiovascular collapse and pneumonia. Complications are the result of dynamic hyperinflation that forms the cornerstone in the pathophysiology of both diseases. The diameter of the smaller airways decreases because of inflammation, bronchospasm, mucus (asthma) and the loss of elastic recoil by emphysema (COPD). This leads in particular to a high airway resistance during expiration and the residue of tidal volume in the lung when the next inspiration begins. The result is dynamic hyperinflation with a continuously increasing lung volume with high pressures, pneumothorax (barotrauma) and hemodynamic collapse as a result. During CMV (pressure- or volume controlled ventilation; PCV or VCV) only the inspiration is controlled while expiration is passive, possibly leading to airway collapse and further dynamic hyperinflation. Besides, both ventilation modes are accompanied by high flow rates leading to a further increase in airway resistance and ventilation pressures. Flow controlled ventilation (FCV) is a mechanical ventilation method that uses a relatively low and constant flow during both inspiration and expiration, thereby decreasing airway resistance and preventing airway collapse during expiration. Besides, FCV has shown to have a higher ventilation efficiency measured by a decrease in minute volume at stable arterial partial pressures of carbon dioxide (PaCO2). This makes FCV a very interesting ventilation mode in intubated patients with an exacerbation of asthma or COPD, possibly decreasing the amount of dynamic hyperinflation and complications in these patients. Although FCV is widely used for hypoxic respiratory failure on the ICU so far no studies have been performed in asthma or COPD patients.

We hypothesize that FCV in intubated patients with an exacerbation of asthma or COPD results in a lower minute volume (MV) and decreased end-inspiratory lung volume (EILV) as a measurement for dynamic hyperinflation compared to VCV.

Objectives: To study the effect of FCV on the MV and EILV compared to VCV.

Study design: Physiological pilot study with a randomized crossover design comparing FCV and VCV.

Study population: Patients with an asthma/COPD exacerbation ≥18 years old receiving CMV.

Intervention: Patients are mechanically ventilated with VCV at baseline. Upon inclusion the EIT-belt and an esophageal balloon are placed to assess the EILV and transpulmonary pressures respectively. Besides, patients are randomized between the sequence of ventilation mode, namely 90 minutes of VCV followed by 90 minutes of FCV or 90 minutes of FCV followed by 90 minutes of VCV. When VCV is switched to FCV the same mechanical ventilator settings are used as in the VCV mode. After half an hour on FCV the PEEP, drivingpressure and flow of FCV are optimized based on the highest compliance and lowest flow matching with a stable PaCO2. VCV is always set according to standard of care. Total time of measurements / study time is 180 minutes.

Main study parameters/endpoints: Primary endpoint is the difference in minute volume after 90 minutes on FCV compared to after 90 minutes of VCV. An important secondary endpoint is the difference in EILV after 30 minutes on FCV compared to after 30 minutes of VCV.

Nature and extent of the burden and risks associated with participation, benefit and group relatedness: All patients are sedated and on CMV, therefore there will be no discomfort for the patient. FCV has been successfully applied during surgery and on the ICU and the patient will be monitored continuously so the clinical team can act directly in case of any adverse event. Lung volume is measured with EIT, a non-invasive, radiation-free monitoring tool. Transpulmonary pressures are measured with an esophageal balloon that is placed in a similar manor as a nasogastric feeding tube. Therefore, overall the risks of this study are limited.

Conditions

See the medical conditions and disease areas that this research is targeting or investigating.

Obstructive Pulmonary Disease Mechanical Ventilation Pressure High Asthma COPD

Study Design

Understand how the trial is structured, including allocation methods, masking strategies, primary purpose, and other design elements.

Allocation Method

RANDOMIZED

Intervention Model

CROSSOVER

Physiological pilot study with a randomized crossover design comparing FCV and VCV

Primary Study Purpose

SUPPORTIVE_CARE

Blinding Strategy

NONE

Study Groups

Review each arm or cohort in the study, along with the interventions and objectives associated with them.

FCV-VCV

90 minutes of FCV followed by 90 minutes of VCV

Group Type EXPERIMENTAL

FCV

Intervention Type DEVICE

90 minutes of FCV

VCV-FCV

90 minutes of VCV followed by 90 minutes of FCV

Group Type EXPERIMENTAL

FCV

Intervention Type DEVICE

90 minutes of FCV

Interventions

Learn about the drugs, procedures, or behavioral strategies being tested and how they are applied within this trial.

FCV

90 minutes of FCV

Intervention Type DEVICE

Other Intervention Names

Discover alternative or legacy names that may be used to describe the listed interventions across different sources.

Flow-controlled ventilation

Eligibility Criteria

Check the participation requirements, including inclusion and exclusion rules, age limits, and whether healthy volunteers are accepted.

Inclusion Criteria

* 18 years or older;
* Provided written informed consent;
* Undergoing controlled mechanical ventilation via an endotracheal tube;
* Reason for intubation being exacerbation of asthma or COPD;
* Intubated ≤72 hours

Exclusion Criteria

* Severe sputum stasis or production requiring frequent bronchial suctioning (more than 5 times per nurse shift)
* Untreated pneumothorax (i.e. no pleural drainage)
* Hemodynamic instability defined as a mean arterial pressure below 60mmHg not responding to fluids and/or vasopressors or a noradrenalin dose \>0.5mcrg/kg/min
* High (\>15 mmHg) or instable (an increase in sedation or osmotherapy is required) intracranial pressure
* An inner tube diameter of 6mm or less
* Anticipating withdrawal of life support and/or shift to palliation as the goal of care
* Inability to perform adequate electrical impedance tomography (EIT) measurements with, e.g.:

* Have a thorax circumference inappropriate for EIT-belt
* Thoracic wounds, bandages or deformities preventing adequate fit of EIT-belt
* Recent (\<7 days) pulmonary surgery including pneumonectomy, lobectomy or lung transplantation
* ICD device present (potential interference with proper functioning of the EIT device and ICD device)
* Excessive subcutaneous emphysema
* Contra-indications for nasogastric tube or inability to perform adequate transpulmonary pressure measurements with, e.g.:

* Recent esophageal surgery
* Prior esophagectomy
* Known presence of esophageal varices
* Severe bleeding disorders

Minimum Eligible Age

18 Years

Maximum Eligible Age

100 Years

Eligible Sex

ALL

Accepts Healthy Volunteers

No