Acute Hypoxemic Respiratory Failure Clinical Trial
Official title:
A Comparison of CPAP Delivered by Helmet and O2 Therapy With a Venturi Mask as First Line Intervention in Early ALI/ARDS
Mechanical ventilation through an endotracheal tube is a lifesaving procedure for acute
respiratory failure. However endotracheal intubation increases patient's discomfort and
stress, and represents one of the most important predisposing factors for developing
nosocomial bacterial pneumonia.
In conscious and cooperative patients non invasive positive pressure ventilation (NPPV) is a
safe and effective mean for treating patients with acute respiratory failure (ARF),
improving gas exchanges and reducing the rate of complication related to mechanical
ventilation. Facial mask, that is the conventional interface for NIV, may induce intolerance
because of pain, discomfort or claustrophobia leading to discontinuation of noninvasive
ventilation and endotracheal intubation. Thus the improvement of the interface between
patient and ventilator seems crucial to achieve a good tolerance allowing the prolonged
application of noninvasive ventilation. Attempting to improve tolerability of patients we
used a new interface consisting in Helmet made in latex-free PVC.
No prospective randomized controlled study has been published on the comparison between
Continuous Positive Airways pressure (CPAP), delivered by an helmet and the medical
treatment with Oxygen supplementation to treat early acute respiratory failure and acute
lung injury.
Aim of the present protocol is to compare the efficacy of CPAP delivered with helmet and
conventional medical treatment with oxygen supplementation via Venturi mask, to prevent ETI
in patients with early hypoxemic ARF ( paO2 /FiO2 below 300).
Prevention of Endotracheal Intubation by NIV and CPAP Mechanical ventilation through an
endotracheal tube is a lifesaving procedure for acute respiratory failure. However
endotracheal intubation increases patient's discomfort and stress, often requiring sedation,
may cause injuries of the tracheal mucosa and tracheal stenosis (1), and represents one of
the most important predisposing factors for developing nosocomial bacterial pneumonia.
In conscious and cooperative patients non invasive positive pressure ventilation (NPPV) is a
safe and effective mean for treating patients with acute respiratory failure (ARF),
improving gas exchanges and reducing the rate of complication related to mechanical
ventilation .
Noninvasive ventilation and CPAP can be performed by of full face mask. Facial mask may
induce intolerance because of pain, discomfort or claustrophobia leading to discontinuation
of noninvasive ventilation and endotracheal intubation. During the early phases of hypoxemic
acute respiratory failure if disconnection from mechanical ventilation occurs, patients can
rapidly deteriorate gas exchanges with potential life threatening consequences. Despite
improvements in facial masks characteristics, skin necrosis may occur in 7% of patients
treated with NPPV for periods exceeding 72 hours.
Attempting to improve tolerability of patients we used a new interface consisting in Helmet
made in latex-free PVC that allows patients to see, read and speech as during noninvasive
pressure support ventilation (NPSV) and CPAP ( Continuos Positive Airways Pressure).
The efficacy of a helmet was recently tested and successfully applied to deliver CPAP as out
of hospital treatment for patients with pulmonary edema. Recently in a matched controlled
study we reported the efficacy of NPPV using the helmet to treat adult patients with
hypoxemic ARF in comparison to NPSV using standard facial mask.
No prospective randomized controlled study has been published on the comparison between
Continuous Positive Airways pressure (CPAP), delivered by an helmet and the medical
treatment with Oxygen supplementation to treat early acute respiratory failure and acute
lung injury.
Aim of the present protocol is to compare the efficacy of CPAP delivered with helmet and
conventional medical treatment with oxygen supplementation via Venturi mask, to prevent ETI
in patients with early hypoxemic ARF ( paO2 /FiO2 less than 300).
Patients enrolled will be randomly assigned to receive either standard treatment with oxygen
supplementation delivered by Venturi mask or CPAP through the Helmet. Computer-generated
random assignments will be concealed in sealed envelopes The ethic committee of the Catholic
University in Rome approved the protocol, and all patients or the next-of-kin will give
written informed consent.
Helmet CPAP
During CPAP, the helmet is connected by conventional tubing to a free flow CPAP generator
(CaStar Flow generator, Starmed, Italy) with an inspiratory flow more than 45 l/min
(Patroniti Intensive Care Med (2003) 29:1680.1687), to avoid the need of a reservoir bag and
the risk of rebreathing
The Helmet (CaStar Flow, Starmed, Italy) is made of transparent latex-free PVC that allows
patient to see, read and interact with the environment. The helmet is secured by two arm-pit
braces at two hooks of the metallic ring that joins the helmet with a seal connection soft
collar around the neck. The helmet is available in three different sizes in order to
ameliorate comfort and a specific seal connector placed in the metallic ring can be used to
allow the passage of a nasogastric tube avoiding air leakage. This connector can be also
used to allow patient drinking through a straw. A multiple value PEEP valve ( range 0-20 cm
H2O)(Starmed PEEP valve Mirandola Italy) is connected to the expiratory port of the Helmet,
where the PEEP value can be confirmed by an anaeroid manometer.
If necessary the helmet can be easily removed and endotracheal intubation can be performed
rapidly.
The patients will be not sedated. CPAP will be initiated with a FiO2 equal to or greater
than 0.5. PEEP levels will start from 5 cmH2O and augmented by 2 cmH2O stepwise if
clinically needed to assure a level of arterial oxygen saturation equal to or greater than
92%.
CPAP level will be reduced progressively on clinical improvement and discontinued if the
patient have a PaO2 / FiO2 above 300 and a RR lower than 30 breaths/min, without PEEP and
activation of the accessory muscles of respiration
Venturi Mask group Patients assigned to the standard treatment group will receive oxygen
supplementation via a Venturi mask starting with a fraction of inspired oxygen equal to or
greater than 0.5, and adjusted to achieve an initial level of arterial oxygen saturation
equal to or greater than 92%.
Oxygen cessation criteria: the patient with a PaO2 / FiO2 above 300 and a RR lower than 30
breaths/min, without activation of the accessory muscles of respiration
Criteria for endotracheal intubation
Patients failing CPAP or standard treatment will be intubated orotracheally with cuffed
endotracheal tubes (internal diameter of 7.5 to 8.5 mm) and mechanically ventilated.
Predetermined criteria for endotracheal intubation will be identical for all groups and will
include one of the following:
the inability of the patient to tolerate the helmet, including discomfort, claustrophobia or
pain.
- PaO2 below 150 and at least, one of the Following
- Loss of alertness or agitation needing sedation
- Signs of exhaustion
- Absence of cough, inability to maintain airway with head in felxion
- Respiratory arrest
- Hemodynamic instability (MAP below 65 mmHg.) frequent recurrent non perfusing
dysarrhythmia
- Cardiac arrest
- Signs of patient distress with accessory muscle recruitment and paradoxical abdominal
motion
- RR above 35 RR/min
- Respiratory acidosis (pH below 7.3 and PaCO2 above 50 mmHg)
Conventional ventilation after the treatment failure Intravenous benzodiazepines (Midazolam)
or propofol will be used for sedation at the moment of intubation, and if possible none of
the patients will receive paralyzing agents. The initial ventilator setting will be
assist-controlled ventilation mode with a delivered tidal volume of 6-7 ml/kilogram IBW and
a initial respiratory rate of 18-25 breaths/min, a PEEP of 5 cmH2O, and a FiO2 of 0.8.
Subsequent changes of the ventilator setting will be done according to the NIH protocol. (N
Engl J Med 2000;342:1301-8.) All patients will be weaned from the ventilator by reducing the
level of pressure support by 4 cmH2O twice and then at 2 hour intervals as tolerated up to 8
cmH2O of pressure support. If the patient will tolerate a pressure support level of 8 cmH2O
and an FiO2 of equal to or less than 0.5, a 2 hour T-piece trial will be initiated(11).
These patients will be extubated if they maintain a respiratory rate less than 30
breaths/min and a PaO2 greater than 75 mm Hg
Plan of experiment Multicenter, randomized controlled clinical trial. Enrolled patients will
be randomly assigned to receive either standard treatment with oxygen supplementation
delivered by Venturi mask or CPAP through a Helmet. Each patient will be observed for the
following days until discontinuation or failure.
Arterial blood gas levels will be determined at baseline, while breathing through Venturi
mask, at 1 hour during CPAP, and at 6-12 hours intervals for the first 24 hours. ABG will be
daily determined for the following days until discontinuation or failure.
End Points and Definitions The primary outcome variable will be the evaluation of the need
for endotracheal intubation.
Secondary end points will include the improvement of gas exchanges, complications not
present on admission (such as ventilator-associated pneumonia or extra-pulmonary sepsis),
duration of ventilatory assistance, length of the hospital stay, and ICU mortality. For each
patient the number of days free of mechanical ventilation will be recorded during the first
28 days after the admission or until hospital discharge.
Improvement in gas exchange are defined as the ability to increase PaO2:FiO2 ratio above 300
or an increase in this ratio of more than 100 from base line.(4-5) Improvement in gas
exchange will be evaluated within 1 hour (initial improvement) after study entry and over
time (sustained improvement). Sustained improvement in gas exchange will be defined as
ability to maintain the defined improvement in PaO2/FiO2 until mechanical ventilation was
discontinued, as confirmed by serial blood gas measurements.
Population of the study Experimental Center This trial is multicenter and involves four
different intensive care units in Italy (Università Cattolica del Sacro Cuore, Università
dell'Insubria-Varese, Università di Torino, Ospedale S. Gerardo di Monza Power of the study
Under the assumptions that the actual difference within the treatment is about 20% (20 vs.
40% intubation rate) with an type 1 error level of 0.05 and with a desired power of 90%,
between Helmet and Venturi group, the sample size is computed like 80 in the Helmet group
and 80 in the Venturi group. Keeping into account a 20% attrition rate about 190 patient
should be enrolled in the study.
The primary end-point will be the proportion of endotracheal intubation in the two groups.
Secondary End-points Secondary end points will be the improvement of gas exchange,
complications not present on admission (such as ventilator-associated pneumonia or
extra-pulmonary sepsis), complications directly related to noninvasive CPAP as skin
breakdown, gastric distension or conjuctivitis, duration of ventilatory assistance, length
of the ICU and hospital stay, ICU and 28 days mortality.
;
Allocation: Randomized, Endpoint Classification: Safety/Efficacy Study, Intervention Model: Parallel Assignment, Masking: Open Label, Primary Purpose: Treatment
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