Neurally-Adjusted Ventilatory Assist for Noninvasive Ventilation via a Helmet in Subjects With COPD Exacerbation: A Physiologic Study

Study Protocol

After each subject's enrollment in the study, NAVA catheter (Maquet Critical Care, Solna, Sweden) was placed in the esophagus and correct positioning was ascertained as previously described.¹⁵ The study was performed by using a standard Servo-i ventilator (Maquet Critical Care) equipped with NAVA module and NIV software for air leaks. All the subjects subsequently underwent two 30-min trials (pressure support through a face mask and NAVA support through a helmet) in random order according to a computer-generated random sequence by using sealed, opaque, numbered envelopes. The envelopes were kept in the head nurse's office. The envelope was opened by the nurse in charge of the subject, and the prescribed sequence of modes was communicated to the investigators.

Settings in both modes of ventilation were titrated to obtain the same ventilatory support provided to the subjects before study entry. In particular, the pressure support through a face mask trial was conducted through a face mask individually selected for each subject based on his or her anthropometric characteristics to minimize air leaks and optimize subject tolerance¹³; the face mask was selected from among 2 different models: FreeMotion RT041 Non Vented Full Face Mask (Fisher and Paykel, Auckland, New Zealand) and PerforMax Face Mask (Philips Respironics, Murrysville, Pennsylvania). The ventilator was set as previously clinically indicated by the attending physician. In particular, inspiratory pressure support was ≥8 cm H₂O to obtain a tidal volume of 6–8 mL/kg of ideal body weight, with the fastest rate of pressurization and cycling that was between 25 and 50% of peak inspiratory flow.¹⁰

The NAVA through a helmet trial was conducted with a new-generation helmet (Castar Next, Intersurgical, Mirandola, Italy) in NAVA, with the NAVA level set at its maximum (ie, 15 cm H₂O/μV), the same PEEP applied during the pressure support through a face mask trial and an upper airway pressure (P_aw) limit to obtain the same overall P_aw applied during the pressure support through a face mask trial.^11,16,17 The trigger sensitivity was set at 0.5 μV, whereas the default cycling was 70% of the peak electrical activity of the diaphragm (EA_di), as fixed by the company.¹⁶ F_IO2 was set to maintain peripheral (S_pO2) between 90% and 94%,¹⁴ and remained unmodified throughout the study period.

Predefined criteria for protocol interruption were the following: (1) the need for emergency intubation to protect the airway; (2) S_pO2 of <86%; (3) acute respiratory acidosis, as defined by P_aCO2 > 50 mm Hg and pH < 7.30; (4) an inability to expectorate secretions; (5) hemodynamic instability (ie, a need for continuous infusion of dopamine or dobutamine of >5 μg/kg/min, norepinephrine of >0.1 μg/kg/min, or vasopressin to maintain mean arterial blood pressure of >60 mm Hg); (6) life-threatening arrhythmias or electrocardiographic signs of ischemia; or (7) Glasgow coma scale decline of ≥2 points.

Data Acquisition and Analysis

Air flow, P_aw, and Ea_di were acquired from the ventilator through an RS232 interface at a sampling rate of 100 Hz and were recorded on a computer with dedicated software (ServoTracker V. 4.0, Maquet Critical Care). The last minute of each trial was manually analyzed off-line by using customized software based on Microsoft Excel Microsoft, Redmond, WA, as previously described.¹⁸ Comfort was assessed through an 11-point numeric rating scale, as previously reported.^9,13,17 Before protocol initiation, all the subjects received a detailed explanation of the numeric rating scale. The subjects evaluated their comfort level at the end of each trial with a number between 0 (worst possible comfort) and 10 (best possible comfort) by using an ICU-adapted large printed scale that included numbers and descriptors. The scores obtained were recorded without additional indications or comments.^9,13,17 At the end of each trial, arterial blood was also sampled for gas analysis.

Mechanical inspiratory time (T_I) and ventilator rate were determined from the flow tracing. Subject's own (neural) breathing frequency and neural T_I were computed from the EA_di tracing. Subjects' own (neural) breathing frequency and T_I were computed from the EA_di tracing. Mechanical T_I/T_tot and neural T_I/T_tot inspiratory duty cycle were calculated as the ratio between mechanical T_I/T_tot and the ratio between neural T_I/T_tot, respectively.^12,13,19 Leaks were computed as the difference between the volume insufflated to the interface and the exhaled volume back to the ventilator multiplied by the (ventilator rate; leaks were expressed as the rate of the inhaled volume over 1 min.^13,19 Moreover, we measured the peak P_aw, the peak inspiratory flow, and the time to reach peak inspiratory flow from the onset of the subject effort.¹³ The peak EA_di was also calculated as the swing from baseline to its peak to assess the respiratory drive.^12,13

The pressurization performance was assessed with the P_aw-time product (PTP) of the first 200 ms computed from the onset of ventilator assistance (PTP₂₀₀), excluding the triggering phase, and with the PTP of the first 300 and 500 ms from the onset of subject effort, indexed to the ideal PTP (index PTP₃₀₀ and index PTP₅₀₀, respectively).^8,12,13,20 The ideal PTP was computed by considering a perfectly squared rectangle on the P_aw-time tracing, with the height of the actual P_aw above PEEP and the width of the time window considered (ie, 0.3 and 0.5 s from the onset of the inspiratory effort, assessed from the EA_di tracing, for index PTP₃₀₀ and index PTP₅₀₀, respectively).^8,12,13,20 The inspiratory trigger delay and the expiratory trigger delay, the PTP during the triggering phase, and the drop in P_aw were computed to evaluate the triggering performance.^8,12,13,20

To assess patient-ventilator synchrony, we calculated the time of synchrony between diaphragm activity and ventilator assistance indexed to the subject's own neural T_I.^8,12,13,20 Asynchronies (ineffective efforts, auto triggering and double triggering) were also assessed and expressed as the asynchrony index, that is, the total number of asynchronous events divided by the number of triggered and not triggered breaths.⁴ The asynchrony index of ≥10% was considered to indicate a clinically relevant rate of asynchronies.⁴

Statistical Analysis

Based on preliminary data, to ascertain an average increase in comfort of 2.0 with an expected SD of 2.0 with α risk of 0.05 and β risk of 0.20, a sample of 10 subjects was deemed necessary.¹² Data were reported as median and 25–75% interquartile, unless otherwise specified. All continuous variables were compared by the Wilcoxon signed-rank test. We compared categorical data by using the Fisher exact test, whereas the Spearman rank correlation test was used to determine the correlation between each individual comfort score and the corresponding PTP₂₀₀, index PTP₃₀₀, index PTP₅₀₀, PTP during the triggering phase, inspiratory trigger delay, peak inspiratory flow, and the time to reach peak inspiratory flow. We considered significant 2-sided P < .05. All the statistical analyses were performed by using the SigmaPlot v. 12.0 (Systat Software, San Jose, California).