A pilot prospective study on closed loop controlled ventilation and oxygenation in ventilated children during the weaning phase

During the study period, all consecutive admitted critically ill children under mechanical ventilation for at least 12 hours, younger than 18 years old, having predicted body weight (PBW) ≥ 3 kg and body mass index < 40 kg/m² were screened daily for the study 5 days a week (Monday to Friday). PBW was the weight at the 50th percentile for age and sex from the National Center of Health Statistics growth chart.

The study was in essence a pilot investigation and was designed primarily to evaluate the safety of the new computerised protocol. Children were therefore included if they fulfilled the following criteria: able to breathe spontaneously; ventilated with proximal airway plateau pressure ≤ 25 cmH₂O, positive end-expiratory pressure (PEEP) ≤ 8 cmH₂O, with fraction of inspired oxygen (FiO₂) ≤ 60% to keep oxygen saturation from pulse oxymetry (SpO₂) ≥ 95%, and arterial partial pressure of CO₂ < 70 mmHg on the last arterial blood gas; endotracheal tube leakage < 20% of the inspired tidal volume (VT), because the new computerised protocol requires correct information on VT; arterial partial pressure of CO₂ versus partial pressure in end-tidal CO₂ (PEtCO₂) difference ≤ 7 mmHg; or not receiving muscle relaxant, vasopressor or inotropic medication (except dopamine < 5 μg/kg/minute).

Children with a previous history of mechanical ventilation (more than 1 month) or tracheotomy, severe neuromuscular disease, cyanotic congenital heart disease and primary pulmonary hypertension were excluded, as well as brain-death children and children receiving palliative care.

An analysis was planned after the inclusion of five patients (run-in phase) because there was no clinical experience of this mode of ventilation. The analysis of the run-in phase showed that children with PBW < 7 kg had an increase in minute ventilation (MV) because of technical reasons (high apparatus dead space with the S1 device due to the proximal flow sensor + mainstream CO₂ analyser in series). The investigators decided to only include children with PBW > 7 kg. The four patients under 7 kg PBW and already included in the run-in phase were not analysed, although they went through the study without adverse effects (see Safety evaluation below).

All included patients were prospectively enrolled in a sequential nonrandomised study during which they received five consecutive 60-minute periods of ventilation (Figure 1): pressure support ventilation (PSV) using the ventilator already connected to the patient (Servo-i; Maquet Gmbh & Co. KG, Rastatt, Germany) with the level of inspiratory pressure (P_insp) set by the attending intensivist prior to the inclusion (PSV_before); adaptive support ventilation (ASV) using a functional S1 prototype ventilator (Hamilton Medical AG); ASV with the CO₂ controller activated (ASV-CO₂); ASV with the CO₂ and the O₂ controller activated (ASV-CO₂-O₂); and PSV using the Servo-i ventilator at the initial level of support (PSV_after).

Throughout the ventilation period with the S1 device and for safety reasons, a trained physician remained at the bedside.

ASV is a ventilatory modality commonly used in adults [11, 12] where, for a given MV set by the user according to the clinical conditions and arterial blood gases, the ventilator automatically selects an optimal combination of respiratory rate (RR) and VT based on the breath-by-breath estimation of the expiratory time constant. The level of support (mandatory rate and P_insp) is automatically adjusted on a breath-by-breath basis to keep the patient as close as possible to the optimal RR and VT. If the patient breathes spontaneously, this mode works as a volume target-pressure regulated mode with a user-set MV guarantee. If not, the ASV mode works as a pressure control mode with a prescribed MV. In ASV, the MV is the parameter that is controlled and set by the user. To further control the VT (and more specifically to reduce the VT) or to limit P_insp, the user must decrease the MV and the maximum P_insp allowed (pressure limitation). At the bench, in doing so it has been recently shown that ASV was able to generate lower VT and P_insp compared with the ARDSnetwork recommendations [13]. However, in some clinical studies when the maximum allowed pressure is permissive (60 cmH₂O), high VT has been reported with ASV [14]. In our study, MV in ASV was set to match the MV measured during PSV_before. PEEP and FiO₂ were set as during PSV_before. The pressure limitation was set to limit the P_insp to 25 cmH₂O.

ASV-CO₂ is an evolution of ASV where MV is not set by the user but is automatically adjusted to keep the patient within ranges of RR and PEtCO₂, captured at the proximal airway using the S1 flow sensor (PN 279331, single-use flow sensor linear between -120 and 120 l/minute with ± 5% error of measure; Hamilton Medical AG) and a mainstream CO₂ analyser (Capnostat 5, mainstream sensor with accuracy ± 5% for PEtCO₂ between 41 and 70 mmHg, dead space 5 ml; Hamilton Medical AG). The target range of RR is defined by a lower limit based on the Otis concept of optimal RR to minimise the work of breathing [15], and an upper limit depending on the actual MV; the higher the MV, the higher the upper RR limit. P_insp increases when the patient RR is above the upper RR limit; P_insp decreases when the patient RR is below the lower RR limit. Filtered PEtCO₂ is present in the background to keep the patient below the upper PEtCO₂ acceptable value (Figure 2). Ventilation changes are made on a breath-by-breath basis.

ASV-CO₂-O₂ includes the above-described ASV-CO₂ regulation plus an automatic adjustment of PEEP and FiO₂ based on SpO₂ monitoring included in the ventilator. SpO₂ is obtained from a finger probe using standard technology, plus proprietary filtering and quality assessment before entering the algorithm: when SpO₂ is below a user-adjustable value, FiO₂ or PEEP is increased (Figure 2). These ventilation changes are made on a breath-by-breath basis. The choice between FiO₂ and PEEP increase is based on the ARDSnetwork tables [16] with user inputs regarding maximal and minimal PEEP values. The FiO₂ controllers and the PEEP controller can be activated or deactivated independently. In the present study both controllers were activated, but according to local policies regarding PEEP settings the minimal PEEP and maximal PEEP were respectively set at 5 and 10 cmH₂O.

The investigators remained at the bedside during the entire duration of the study and were allowed to switch back to manual adjustment of the settings. As for any mode of ventilation, the user has to set alarms for VT, for airway pressure as well as for monitoring parameters such as SpO₂ and PEtCO₂.

Patient characteristics including demographic data, diagnosis, severity scores, clinical data at inclusion and outcomes were collected from the charts. When connected to the S1 device, monitoring values (including SpO₂, PEtCO₂ and mechanical ventilation monitoring), settings and alarms were recorded on a breath-by-breath basis using a dedicated data-logging system attached to the ventilator. Minute-to-minute data from the Servo-i were collected using a compact flash reader connected to the device.

Breath-by-breath data were analysed ex vivo to calculate the number of normal breaths as defined by 10 breaths/minute < RR < 40 breaths/minute, VT > 5 ml/kg PBW and 25 mmHg < PEtCO₂ < 55 mmHg. The primary end point of the study was the percentage of time spent with normal ventilation, defined as the number of normal breaths out of the total number of breaths collected. During PSV_before and PSV_after, PEtCO₂ was dropped from the definition as it was not recorded with the Servo-i ventilator.

The number of ventilation setting changes was compared between the five consecutive 60-minute periods of ventilation. A ventilation setting change corresponded to a modification of PEEP or FiO₂ in any ventilation mode, a change of P_insp in PSV or a change of minute volume in ASV, ASV-CO₂ or ASV-CO₂-O₂.

Safety was evaluated by recording adverse events as defined by ISO 14155 standards (ISO 14971:2007, Medical devices -- Application of risk management to medical devices) and by the number of switch back to PSV or to controlled ventilation by the intensivist present at the bedside, whatever the reason. The protocol was terminated and the child ventilated with the previous conventional ventilation if a sustained change was demonstrated in any of the following: decrease in SpO₂ < 92% requiring increase in FIO₂ > 60%; increase in PEtCO₂ above the value before connection with the S1 device, requiring an increase of positive P_insp > 25 cmH₂O above PEEP; increase in heart rate > 180 beats/minute for 15 minutes; increase in RR > 60 breaths/minute for 15 minutes; or uncontrolled agitation.

There were no previously existing data on the percentage of time spent with normal ventilation in children during mechanical ventilation. A similar study in adults observed that patients in PSV mode spent 66 ± 23% in the normal ventilation range compared with 93 ± 8% of patients ventilated with a closed loop computerised protocol [17]. From this study [17], we calculated that 16 patients would be required to find a statistical difference for such a difference with an α risk of 0.05 and a β risk of 0.9.