Mechanical Ventilation Complication Clinical Trial
— DPNAVAOfficial title:
Driving Pressure Variation During Proportional Assisted Ventilation: Comparison Between NAVA and PSV
Assisted ventilation represents, nowadays, the preferred ventilation mode in clinical
practice.It has been shown that assisted ventilation modes improve ventilation/perfusion
matching, descrease risk of Ventilator induced lung injury and muscle atrophy and have less
influence on haemodynamic function.
However, PSV (Pressure Support Ventilation) is not free from complications: it may worsen or
cause lung injuries by increasing alveolar and intrathoracic negative pressure and by loosing
control on Tidal Volume (Vt). Indeed, it has been demonstrated that Vt is the main factor
related to VILI.
It has been shown that lower Vt and higher PEEP can improve clinical outcome only if
associated with a simultaneous reduction in Driving Pressure. Increase in Driving Pressure
resulted strongly associated with negative outcomes, especially if higher than 15 cm H2O.
PSV is currently the most used assisted ventilation mode. NAVA (Neurally Adjusted Ventilatory
Assist) is a ventilation mode in which the diaphragmatic electrical activity (EAdi) is used
as a trigger to start a mechanical breath, applying positive pressure during patient's
inspiration. Diaphragmatic electrical activity (EAdi) can be detected by a particular
nasogastric tube (EAdi catheter). EAdi is the currently available signal closest to the
neural breathing centers, which can estimate the patient's respiratory drive, if phrenic
nerves are not damaged. It has been demonstrated that NAVA ventilation can reduce the
incidence of patient-ventilator asynchronies, because the delivery of the support and the
cycling between inspiration and expiration are completely controlled by the patient.
However, although PSV and NAVA have been widely compared in many investigations, up to now
there are no studies about driving pressure variation during these two modalities of
mechanical assisted ventilation. The aim of this study is to measure changes in driving
pressure at different levels of ventilatory assistance in PSV and NAVA ventilation modes.
Secondary end points are respiratory mechanics indices and patient/ventilator related
asynchrony evaluation and comparison.
Status | Recruiting |
Enrollment | 20 |
Est. completion date | November 1, 2020 |
Est. primary completion date | December 1, 2019 |
Accepts healthy volunteers | No |
Gender | All |
Age group | 18 Years and older |
Eligibility |
Inclusion Criteria: - Age >18 years - Every patients undergoing partial assisted mechanical ventilation Exclusion Criteria: - Gastro-esophageal surgery in the previous 12 months; - Gastro-esophageal bleeding in the previous 30 days; - Esophageal varices history; - Maxillo-facial surgery or trauma; - Haemodinamic instability despite adequate fluid infusion (i.e. need for continuous infusion epinephrine or vasopressin or dopamine at a dose greater than 5 mcg/kg/min to obtain systolic pressure > 90 mmHg); - Body temperature > 38° C during the study screening; - Coagulation disorders (INR > 1.5, aPTT > 44 sec); - Vt < 8 ml/kg with minimum inspiratory effort of 8 cmH2O; - Inclusion in other research protocols |
Country | Name | City | State |
---|---|---|---|
Italy | A.O.U Maggiore della Carità | Novara |
Lead Sponsor | Collaborator |
---|---|
Azienda Ospedaliero Universitaria Maggiore della Carita |
Italy,
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* Note: There are 23 references in all — Click here to view all references
Type | Measure | Description | Time frame | Safety issue |
---|---|---|---|---|
Primary | Driving pressure in PSV and NAVA | Driving Pressure measurements in in PSV and NAVA (cmH2O) | At the end of every 20 minutes lasting ventilation trial. | |
Secondary | Respiratory mechanical indices variation | electrical diaphragmatic activity (mcvolts) | At the end of every 20 minutes lasting ventilation trial. | |
Secondary | Patient/ventilator interaction | asynchrony index (normal value < 10%; pathological value > 10%) | At the end of every 20 minutes lasting ventilation trial. | |
Secondary | Patient/ventilator interaction | time of synchrony (msec) | At the end of every 20 minutes lasting ventilation trial. | |
Secondary | diaphragm ultrasound | evaluation of diaphragm performance at each trial | At the end of every 20 minutes lasting ventilation trial. |
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