Noninvasive ventilation for acute respiratory failure: a prospective randomised placebo-controlled trial

Study location and patient selection

The study protocol was approved by the Ethical Practices Committee of the authors' hospital in accordance with the principles of good clinical practice. Informed oral consent was obtained from all study participants. The study was conducted in the ED of an urban university teaching hospital (884 beds). During a 2-yr period (1999–2000), patients with acute respiratory distress secondary to either an acute exacerbation of COPD or APO were eligible for this investigation. Cardiogenic pulmonary oedema was defined as orthopnoea, bibasilar crackles, bilateral perihilar infiltrates on chest radiograph with cardiomegaly and a compatible clinical history. An acute exacerbation of COPD was defined as acute respiratory distress in a cigarette smoker with a known history of long-lasting dyspnoea on exertion with frequent exacerbations and cough, and mucus hyperproduction, without symptoms or signs of other specific causes (absence of pneumothorax, pneumonia, pleural effusion, no reason to suspect an episode of pulmonary embolism). Patients were entered into the study if they were aged >18 yrs and had evidence of ARF as demonstrated by three of the following criteria: acute onset of moderate-to-severe dyspnoea as assessed by the ED physician who took care of the patient; a respiratory rate >30 (or <10) breaths·min⁻¹; hypoxaemia (oxygen tension in arterial blood (P_a,O2) <7.3 kPa (55 mmHg) (on room air)) or need for O₂ supplementation; respiratory acidosis (pH <7.33). The diagnosis of ARF and the decision to include the patient into the study was the responsibility of the ED physician (independent of the investigators). Patients were excluded from this investigation if they had any of the following: 1) an immediate indication for endotracheal intubation (respiratory and/or cardiac arrest); 2) major unrest; 3) haemodynamic instability despite a fluid challenge; 4) facial or thoracic trauma; 5) lack of cooperation; 6) difficult adaptation of a facial mask to a patient's facial anatomy; 6) clinical suspicion of pulmonary embolism; 7) retrosternal pain suggestive of a myocardial ischaemia even with a normal admission electrocardiogram (ECG).

Study design

The trial was designed to enrol 60 patients (on the basis of previous studies, the percentage of patients expected to respond to conventional therapy at 30 and 70% NPPV was evaluated). Therefore, with 30 patients per group, there was a 95% chance of rejecting the null hypothesis 18. Planned interim analysis was performed after 20 and 40 patients had been enrolled. Patients were eligible into the study if, after an initial period of medical treatment, the attending physician judged that intubation and mechanical ventilation was to be considered. The following initial treatments were administered: supplemental O₂, intravenous vasodilators (isosorbide dinitrate 2 mg·h⁻¹) and intravenous diuretics (furosemide 40 mg) for cardiogenic pulmonary oedema and; supplemental O₂, bronchodilator-aerosol therapy (fenoterol 1,500 µg and ipratropium bromide 0.4 mg) repeated every 20 min and intravenous glucocorticoids (methylprednisolone 80 mg) for acute exacerbation of COPD. Patients not improving under this treatment were included into the study while this treatment continued. Patients were randomly assigned to receive conventional medical therapy plus two-level NPPV (bi-level NPPV) or conventional medical therapy plus “placebo” NPPV. Randomisation was performed using opaque, sealed envelopes which were opened at the time of inclusion into the study by batches of 20 envelopes. The study treatment was continued until the attending physician (who was continuously present throughout the study at the bedside) interrupted the treatment either after the patient improved or after the treatment was considered to have failed. Failure was defined in advance as a deterioration in clinical status including all of the following: dyspnoea, respiratory and/or heart frequency, sweating and agitation or deterioration in blood gases and/or in haemodynamic status. Success was defined as clear improvement in both the blood gases and the clinical status. Treatment success led to study end. In case of treatment failure, endotracheal intubation was applied to patients in the active NPPV group. Patients in the placebo group, in whom intubation was deemed necessary, were submitted first to active NPPV (rescue protocol). At all times the attending physician could decide to interrupt the study.

Active bi-level noninvasive positive-pressure ventilation protocol

Patients randomised to receive bi-level NPPV were evaluated by two investigators. With respect to the time of arrival of the patient to the ED, this implied a delay dependent on two factors: the time necessary for the ED physician to decide inclusion and the time necessary for the investigators to arrive to the ED and start the protocol. Bi-level NPPV was delivered by a ventilatory support system (BiPAP® ST/D 30; Respironics, Inc., Murrysville, PA, USA) with a standard expiratory port. Bi-level NPPV was instituted with a face mask (Bird, Bird Corp., CA, USA) with the patient in a semirecumbent position. The expiratory pressure was set at the minimal pressure level (4 cmH₂O) and the inspiratory pressure was set at 10 cmH₂O. The machine was used in the assist-control mode with a backup frequency of 10·min⁻¹. In all patients, the inspiratory pressure was increased by 2 cm of water steps, until the patient showed signs of discomfort (increasing sensation of dyspnoea) or leaks were observed between the face mask and the skin or a pressure of 20 cmH₂O was reached. Thereafter, expiratory pressure was similarly increased until discomfort appeared. A gastric tube was not used. During the institution of bi-level NPPV, O₂ was added with a nasal catheter inside the mask as needed to obtain a saturation of 90% (assessed by pulse oxymetry).

Placebo noninvasive positive-pressure ventilation protocol

The design of the placebo NPPV protocol was strictly the same as the active bi-level NPPV protocol. Placebo-device ventilation was delivered by the same ventilatory support system. In this arm of the protocol, the T-connector piece of the device between the mask and the tubing was substituted by a specially designed T-connector with several holes. With this pierced T-connector, the inspiratory and expiratory pressures delivered through the face mask were equal to zero. The influence of the placebo NPPV on the respiratory work of breathing (WOB) and its rebreathing (dead space) effect had been assessed previously in five and seven normal subjects respectively (see below) and were found to result in no significant change in WOB or increase in end-tidal carbon dioxide (P_ET,CO2).

During the institution of this placebo-device ventilation, O₂ was added with a nasal catheter inside the mask as needed to obtain a saturation of 90%.

Outcome measures

The main outcome measure was the difference in the number of patients failing noninvasive ventilation in each arm of the study. For the active arm, failure was defined as the need for endotracheal intubation; for the placebo arm, failure was defined as the need to stop placebo NPPV and to cross over to active ventilation (either noninvasive ventilation or, if this failed, through endotracheal intubation). As secondary end points, the effects of the ventilatory mode on the clinical and arterial-blood gas parameters, and on sternocleidomastoid muscle activity were evaluated. Hospital mortality, admission to the ICU, the length of ED stay, the length of ICU stay and the length of hospital stay were also assessed.

Physiological measurements

During the clinical study, the intensity of dyspnoea was measured by a 10-cm long visual analogue scale with 0 measuring normal breathing and 10 unbearable dyspnoea. Dyspnoea was assessed by the patient, and also by the nursing team and the investigators, at different times throughout the protocol (see below). The arterial blood gases (pH, P_a,O2, carbon dioxide tension in arterial blood (P_a,CO2) and arterial oxygen saturation) were measured at the time of randomisation, after 20 min of active or sham ventilation, and at the end of ventilatory assistance. The following parameters were continuously recorded in digital form: ECG from three surface electrodes placed on the chest wall, pulse rate and pulse oxymetry from a Datex oxymeter (Datex, Helsinki, Finland) equipped with a finger probe, systolic and diastolic blood pressure with an arm-brassard sphygmomanometer (Datex), the thoracic and abdominal respiratory movements and their sum obtained with an uncalibrated respiratory inductive plethysmograph (Respitrace®, Ambulatory Monitoring, Ardsley, NY, USA), the electromyogram (EMG) of the sternocleidomastoid activity obtained from surface electrodes placed upon the sternocleidomastoid muscles. All signals were digitised and recorded on a dedicated device, specially constructed for this study. In addition to the above signals, the BiPAP® output signals corresponding to inspiratory and expiratory pressures, flow, estimated leaks and tidal volume were also entered into the recording device.

The cardiac enzymes (creatine kinase (CPK), glutamic oxaloacetic transaminase (GOT), lactate dehydrogenase (LDH), Troponine) were also measured on inclusion into the study. The complications of bi-level NPPV (skin damage, gastric dilatation, vomiting) were recorded.

Influence of placebo noninvasive positive-pressure ventilation protocol on the work of breathing and carbon dioxide rebreathing

WOB was assessed in five normal volunteers by simultaneously recording the tidal volume with a calibrated inductive plethysmograph, and transpulmonary pressure with an oesophageal balloon positioned 40 cm from the nares. Measurements were performed during a 1-min stable-breathing period under three conditions: spontaneous breathing; breathing spontaneously but with the facial mask placed upon the face; spontaneous breathing with the placebo NPPV device. Transpulmonary pressure was plotted against tidal volume for all recorded breaths, and the mean WOB was calculated per litre of tidal volume.

The CO₂ rebreathing effects of the placebo NPPV were measured in a similar way in another group of seven normal subjects, by recording the P_ET,CO2 using a hollow nasal sampling device (Datex CO₂ analyser). Measurements were performed during a 1 min stable-state period during spontaneous breathing, application of the facial mask upon the face, and application of placebo NPPV.

Statistical analysis

Values are presented as mean±sd. T-tests for paired and unpaired samples were used to compare the variables. When more than two samples had to be compared, one-way analysis of variance (ANOVA) was used. One-way ANOVA with repeated data was used to compare the frequency of breathing. For WOB and P_ET,CO2 comparisons, the Wilcoxon-rank test was used.

Patients

During the study period, ∼1,300 patients were admitted to the ED for acute respiratory distress. A total of 187 of these patients had a diagnosis of APO or acute exacerbation of COPD. The investigators were contacted for this study in 65 cases (37 acute exacerbations of COPD and 28 APO). Twenty patients (30.7%) were enrolled into the study. Of the remaining 45 patients: seven (10.8%) required immediate endotracheal intubation; eight (12.2%) had chest pain or evidence of cardiac ischaemia; 11 (16.9 %) had no criteria for inclusion; seven (10.8%) patients with COPD exacerbation had hypoxaemic pneumonia; eight (12.2%) patients were not enrolled because the two investigators were not available; two (3%) patients refused inclusion in the study; one (1.5%) patient had cardiogenic pulmonary oedema secondary to chronic renal failure, and was on chronic haemodialysis; and one (1.5%) patient with COPD had hypercapnia secondary to excessive absorption of benzodiazepines.

In the study population (11 males), 10 patients were assigned to each group. The mean age of the patients was 74±8.4 yrs (range 52–89 yrs). Eight patients (40%) had APO and 12 (60%) had acute exacerbation of COPD. No patient included in the study had signs of acute coronary ischaemia. On the admission chest radiograph no patient had evidence of pneumothorax or pneumonia. The time between admission to the ED and the decision by the ED physician to propose the inclusion in this protocol was 55.9±106 min in the placebo group and 82.8±216 min in the active bi-level NPPV group. The time needed to begin the noninvasive ventilation after inclusion was similar in the two groups (21±6.8 min in the placebo group, 24±15.5 min in the active group). The baseline characteristics of the two groups were similar. As shown in table 1⇓, at the time of inclusion all patients had moderate-to-severe dyspnoea when self-assessed and when assessed by the care team; all had pallor and/or cyanosis, and most had sweating or agitation. Table 2⇓ shows that all patients were tachycardic and tachypnoeic; all needed O₂ supplementation and all but four were acidotic. The initial vital signs and the blood gases of the two groups were similar.

Evolution of patients under placebo noninvasive positive-pressure ventilation

After a mean of 29±17 min of placebo NPPV plus conventional medical treatment, all 10 patients had experienced a clinical deterioration with persistency of tachypnoea (initial respiratory rate 37.5±7.3, final 37.7±3.6 (ns)) (fig. 1⇓) and tachycardia (initial cardiac frequency 125.8±20.3, final 136.8±21.6 (p<0.01)), major dyspnoea and sweating, agitation in nine patients and cyanosis in six patients. This clinical deterioration was not paralleled by a worsening in arterial blood gases, which remained unchanged. The sternocleidomastoid EMG activity also remained unchanged or increased during this period (fig. 2⇓). At this point in time, the attending physician recommended that all 10 patients be intubated and mechanically ventilated (table 3⇓).

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Fig. 1.—

Evolution of the respiratory rate in the two groups of patients. “T0” refers to values at the time of inclusion. Note that the “End” time differs for both groups (see text for details). One-way analysis of variance with repeated data showed no significant difference in the placebo group (•), and a significant decrease in the active noninvasive positive-pressure ventilation (NPPV) group (▪) (p<0.001).

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Fig. 2.—

Evolution of the sternocleidomastoid (SCM) electromyogram (EMG) activity throughout the study period in one patient: a) conventional medical therapy; b) end of placebo noninvasive positive-pressure ventilation (NPPV); c) initiation of two-level NPPV; d) 1-min after bi-level NPPV; e) 11-min after bi-level NPPV. In each plot, the following signals are displayed from top to bottom: electrocardiogram (ECG); EMG of the SCM activity obtained from surface electrodes placed upon the left and right SCM muscles; and thoracic and abdominal movements obtained with a respiratory inductive plethysmograph. Note the prominent activity of SCM muscles with conventional medical therapy that persists at the end of placebo NPPV. Upon institution of the rescue protocol (active NPPV), note the decrease in the EMG signal amplitude.

Evolution of patients under active noninvasive positive-pressure ventilation

After a mean of 95±29 min of active NPPV and conventional medical treatment (significantly longer than the placebo NPPV period), the attending physician recommended that NPPV could be safely discontinued in all 10 patients (table 3⇑). Active NPPV treatment (mean positive-inspiratory pressure 17.5±2.9 cmH₂O, mean positive-expiratory pressure 7±1.64 cmH₂O) was characterised by a rapid clinical improvement, with decreases in respiratory rate (initial 36.8±11.7, final 21.6±10.2 (p=0.01)) (fig. 1⇑) and cardiac frequency (initial 122.4±22.09, final 105.9±27.5 (p=0.02)), decreases in dyspnoea, and improvements in acidosis and hypercapnia (all statistically significant, see table 4⇓). Upon application of NPPV the sternocleidomastoid EMG activity rapidly declined and remained at low levels throughout the rest of the treatment period.

Evolution of the placebo group under active noninvasive positive-pressure ventilation (rescue protocol)

The 10 patients failing placebo NPPV were put on active NPPV at the time when the decision to use intubation and mechanical ventilation by the attending physician was made. Seven of these 10 patients experienced a rapid clinical and blood-gases improvement, with decreases in respiratory rates (initial 37.7±3.6, final 23.6±4.6 (p=0.005)) and cardiac frequency (initial 136.8±21.6, final 103.7±24 (p=0.005)), dyspnoea sensation, acidosis and hypercapnia, and increases in P_a,O2 (all statistically significant, see table 4⇑). The sternocleidomastoid EMG activity rapidly declined and remained at low values throughout the 63±34 min of duration of the rescue protocol (fig. 2⇑).

Three patients failed the active NPPV rescue treatment and were finally intubated and mechanically ventilated (table 3⇑). Two of these patients presented with haemodynamic shock after institution of the active bi-level NPPV. ECG showed abnormal left-ventricular function (<25% ECG estimated ejection fraction). Another patient was intubated as no signs of improvement with active bi-level NPPV were seen. A second chest radiograph revealed an asymmetry of the two hemithoraces. A computed tomography scan of the thorax showed an anterior-right pneumothorax.

Patient outcomes

No patient died in the first 24 h after admission. Three patients died afterwards (two in the active group and one in the placebo group). The causes of death in the active bi-level NPPV group were end-stage cardiac failure (after 3 days) and a haemorrhagic complication of a gastric cancer unknown at admission in a patient with COPD (after 6 days). In the placebo group, the cause of death was end-stage cardiac failure. This patient was one of the two patients showing signs of cardiogenic shock upon institution of active NPPV (rescue protocol) after failing on placebo NPPV, and died on hospitalisation day 15. Five patients were discharged from the ED to the wards. Fifteen patients were admitted to the ICU after discharge from the ED (eight in the placebo group and seven in the active bi-level NPPV group). Ten of these patients received further treatment with NPPV in the ICU (three in the active and six in the placebo groups) for an average of 20 h during the first day in ICU. There was no difference in the ED length of stay (active NPPV 474±438 min, placebo NPPV 309±184 min) or in the total hospital length of stay (active NPPV 16±13.6 days, placebo NPPV 17.6±14.3 days), whereas there was a trend towards a greater ICU length of stay in the placebo group (active NPPV 2.7±3.5 days, placebo NPPV 5.4±5.6 days).

Work of breathing and end-tidal carbon dioxide

The results of these experiments showed that the placebo NPPV device resulted in no change in the work of breathing or in P_ET,CO2, whereas the mask applied without the placebo NPPV led to an increase in P_ET,CO2 but no change in WOB. The mean values for WOB, expressed as WOB·L of tidal volume⁻¹ were as follows: spontaneous breathing 0.186±0.064 Joules (J)·L⁻¹, face mask 0.192±0.079 J·L⁻¹, placebo NPPV 0.185±0.072 J·L⁻¹, with no significant difference between these values as determined by the Wilcoxon test. The respective P_ET,CO2 values in kPa (mmHg) were: spontaneous breathing 5.0±0.4 (37.82±2.99), face mask 4.5±0.4 (34.04±2.92), placebo NPPV 5.0±0.4 (37.96±3) (p<0.03 for face mask versus spontaneous breathing, p<0.02 for face mask versus placebo NPPV, p=0.74 for spontaneous breathing versus placebo NPPV, all determined by the Wilcoxon test).