Effect of varying the pressurisation rate during noninvasive pressure support ventilation

Measurements

Arterial blood gases were measured in blood taken from a radial artery in 10 patients. Flow at the airway opening was measured with a heated pneumotachograph (Hans-Rudolf 3700; Kansas City, KS, USA) and a differential pressure transducer (Honeywell, Freeport, IL, USA; ±300 cm H₂O) placed between the mask and the Y‐piece of the ventilator. Tidal volume (V_Tinsp) was obtained by integration of the flow. The breathing pattern was measured from the flow signal. V_Texp was used for data analysis. Inspiratory time (t_I), expiratory time (t_E) and total respiratory time were calculated on the flow trace. The ratio of expired volume over V_Tinsp to quantify the amount of air-leaks was also measured 15.

Airway pressure (Honeywell; ±300 cm H₂O) was measured from a side port between the pneumotachograph and the face mask. Oesophageal and gastric pressures were measured with a balloon-catheter system. To this aim, an oesophageal balloon was positioned at the lower third of the oesophagus, filled with 0.5 mL of air and a gastric balloon filled with 1 mL of air. The proper position of the balloon was verified using the occlusion test 16. Transdiaphragmatic pressure (P_di) was calculated as the difference between gastric (P_ga) and oesophageal (P_oes) pressure.

The pressure time integrals of the diaphragm (PTP_di) and the other inspiratory muscles (PTP_oes) were calculated per breath and per minute 1. The ratio between the neural t_I over the mechanical inspiratory time (t_Ivent) was calculated 17. The t_I was recorded from the point of rapid decline in P_oes to the lowest point in P_oes, while the t_Ivent was calculated on the flow trace from the onset of the inspiratory flow to the zero flow crossing. Expiratory muscle recruitment during the different trials was assessed by measuring the rise in P_ga during expiration from its end-inspiratory level to the maximum at end-expiration 18, 19. The dynamic intrinsic positive end-expiratory pressure (PEEPi,dyn) was obtained from the P_di signal, as the value of P_di at the moment of zero flow 20. Figure 1⇓ shows the methods of measuring t_I, mechanical inspiratory time, and PEEPi,dyn. The number of so-called wasted or ineffective efforts, an index of patient/ventilator mismatching, was also calculated as previously described 14.

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Fig. 1.—

racings obtained in a representative patient, and illustrating the methods of calculation of the neural inspiratory time (^#), the mechanical inspiratory time (^¶), and the dynamic intrinsic positive end-expiratory pressure (⁺). V: flow; P_di: transdiaphragmatic pressure; P_oes: oesophageal pressure.

The patient's tolerance to ventilation was evaluated on a visual analogue scale. This scale has been used and validated in previous studies and has five scores: 1) bad; 2) poor; 3) sufficient; 4) good; and 5) very good 21. The patients were asked by the respiratory therapist to answer the following question: “How do you feel your breathing is at this moment”. For each condition tested, the patient placed a finger on the number that best represented the intensity of their dyspnoea.

Protocol

The patients were studied in a semirecumbent position in order to obtain an accurate P_oes signal. At the beginning of the trial the patients were asked to breath for a few minutes (between 5 and 10) without any ventilatory assistance (baseline recordings). The physiological data were recorded during four randomised trials, each with different pressurisation rates over 20 min, separated by a return to spontaneous breathing for 10 min. The randomisation of the trials was obtained by a computerised program, developed ad hoc, in order to distribute the sequence evenly. The Cesar ventilator offers the option of modulating the pressurisation rate according to the gradient chosen (cmH₂O·s⁻¹) and the patient's inspiratory activity, so that a pressure plateau is reached after a variable time. Inspiration is pressure triggered and the inspiratory pressure ceases when the flow falls to <5 L·s⁻¹. In a preliminary pilot study performed on four patients the physiological changes (without the use of the catheter/balloon system) induced by six different pressurisation rates were assessed. The level of 150 cmH₂O·s⁻¹ produced a comparable amount of air leaks and discomfort to the patients, as did the level of 200 cmH₂O·s⁻¹. Therefore, the slowest (30 cmH₂O·s⁻¹) and fastest (200 cmH₂O·s⁻¹) pressurisation rates allowed by the Cesar ventilator and two intermediate levels (80 cmH₂O·s⁻¹ and 120 cmH₂O·s⁻¹) were chosen for analysis.

Data obtained from the average of 3 min of recordings (usually the last three), were considered for analysis. At the end of each trial the patient's comfort of breathing and arterial blood gases were also recorded. All signals were collected using a personal computer equipped with an A/D board, and stored at a sampling rate of 100 Hz.

Results are presented as mean±sd for continuous variables, as frequency or percentage for the nominal variables and as median (quartiles or range) for the ordinal variables. Comparisons for each sequence and each continuous variable were performed with one-way analysis of variance for repeated measures. Post hoc comparisons between sequences were performed by using the Duncan's test.

To compare repeated measures for an ordinal variable (patient tolerance) the Friedman test was used, while internal comparisons were performed using a nonparametrical test formultiple post hoc comparisons. All tests were two-sided. A p‐value <0.05 was considered statistically significant.

Tolerance to ventilation and air leaks

In a physiological study performed in stable, not hypercapnic COPD patients ventilated in assisted-control mode when the ventilator inflation time was shortened by increasing flow, respiratory frequency increased but so did the time available for exhalation, with a small but significant decrease in intrinsic positive end-expiratory pressure and inspiratory effort. Thus, these ventilatory settings, aimed at reducing inflation time (i.e. increasing the pressurisation rate), could be clinically useful 22.

During invasive PSV, a high initial flow rate was also shown to decrease the work of breathing and mouth occlusion pressure after 100 milliseconds without causing major alterations in breathing pattern and gas exchange, so that the investigators concluded that it was logical the use a high inspiratory flow or a very fast pressurisation rate to ventilate these patients in order to minimise the work of breathing 11, 12.

The objectives of mechanical ventilation are to provide adequate oxygenation, correct acidosis and reduce the work of breathing 23. There is now solid evidence that NIV should be the first line of treatment for moderate-to-severe acute hypercapnic respiratory failure 24. It has also been shown that for the same level of inspiratory support, noninvasive PSV is physiologically and clinically similar to PSV delivered through an endotracheal tube 25. However, these results areonly achieved if NIV is set properly and the patient's acceptance and tolerance of the procedure are optimal. Several clinical studies have reported that lack of compliance to ventilation is one of the major causes of failure in both acute hypercapnic and pure hypoxic respiratory failure 26–28.

One of the factors affecting compliance to NIV is probably the presence of air leaks. A large, multicentre survey recently demonstrated that air leaks were significantly more frequent among the patients in whom ventilation failed 5. Air leaks during noninvasive continuous airway pressure may lead to high unidirectional airflow, which causes a large increase in nasal resistance 29, so that the likelihood of success, especially when NIV is chronically administered, may be lower.

The current study clearly shows that setting the ventilator with the fastest pressurisation rate decreased the acceptance by the patients and that the air leaks increased. Since the inspiratory mechanical time, calculated on the flow trace, was not statistically different in the various runs, it may be predicted that the very rapid achievement of the preset inspiratory plateau pressure would lead to a higher V_T, while this was not the case because of the ∼20% difference between the inspired and expired V_Ts. Nevertheless, it is worth noting that during the different runs the patients were strictly supervised by a respiratory therapist, and that great attention was taken to minimise the problem of leaks. It is likely that once this direct and constant checking is no longer present, the V_T could decrease further. From a clinical point of view massive leaks may be responsible not only for poor tolerance but also for potential unbalance between the patient and the ventilator, especially when using ICU or home-care ventilator not specifically designed to compensate for air leaks. In the present study the authors used a so-called previous generation ventilator that has been shown to underperform compared with the new generation ventilators 30, so that the results from the current study cannot necessarily be extrapolated to all the ventilators available. Nonetheless, patient/ventilator mismatching 14 was not observed in the current study at this very high pressurisation rate. It was shown in a bench study that only very massive leaks around the mask (i.e. >50% of V_T) were associated, for an inspiratory pressure level of 16 cmH₂O, with a failure of the inspiratory flow delivered by the ventilator to reach the expiratory trigger threshold 31. The tolerance to ventilation was not influenced by the level of inspiratory support required by the patients, since the authors were unable to find any statistical correlation between the PSV level and the pressurisation rate that provided the best comfort.

Diaphragm function and breathing pattern

This study has confirmed most of the results obtained during invasive ventilation. The pioneering studies were conducted on groups of heterogeneous patients, with no measurements of respiratory mechanics 9, 10. More recently, Bonmarchand and coworkers 11, 12 demonstrated that a fast pressurisation rate in COPD patients requiring invasive mechanical ventilation decreased the work of breathing, but not the level of dynamic PEEPi.

The PTP_di is an index of diaphragm oxygen consumption and depends on the time of inspiration and the tidal P_di generated during each inspiration 1. Since the different pressurisation rate in the current study did not significantly influence the respiratory timing, the increase in the metabolic consumption was presumably due to the use of a higher portion of P_di. It is rather surprising that the t_I was not significantly shorter with the faster pressurisation rate, and these findings are in contrast with data from most of the studies performed using a pressure assisted mode. The gold standard for evaluating respiratory timing is the respiratory muscle electromyogram (EMG), however for clinical use it is conventionally calculated on the flow trace. From among the surrogate methods of estimation, the bias errors are least when the neural t_I is taken from the P_oes trace 17. The t_I/t_Ivent ratio was significantly shorter with the highest pressurisation rate, so that the reduction in PTP_di was probably due to the shorter contraction time. A reduction in the inspiratory effort may also occur during a high pressurisation rate, since this may help to compensate for time-constant dyshomogeneity likely to be present in decompensated COPD patients 22.

It has also been shown that at high levels of PSV many COPD patients show expiratory muscle activation during the inflation phase 32, indicating that the patient may be fighting the ventilator. In the present study this recruitment was recorded by the so-called expiratory increase in P_ga, which has been shown to correlate with transversus abdominis EMG activity 17. Most of the patients showed minimal expiratory muscle activation even at the highest pressurisation rate, and this is in contrast with some previous studies 18, 19, 33. However, these studies were performed in selected patients who exhibited clinically obvious abdominal muscle activity 19, 33, and normal subjects 18 in whom airflow limitation was induced using a Starling resistor. The current study was performed in a general unselected population of COPD patients, in whom the values of P_ga expired rise is likely to be lower, since the patients in the current study were already recovering from the episode of acute respiratory failure.

Clinical implication

As previously discussed the main goals of mechanical ventilation are to improve gas exchange and reduce the work of breathing 23. Arterial blood gases were found to be similar with all the settings, and this may be due to the relatively short period of each trial, while the inspiratory effort was reduced most significantly by the highest pressurisation rate.

Although the current study was performed in patients recovering from an acute exacerbation of COPD, the results may be of greater interest for the chronic situation in which the respiratory pattern is quite similar to that observed in the present investigation. In the first period of acute respiratory failure, t_I is usually much shorter and inspiratory flow higher, so that it is likely that the patients may need faster pressurisation rates. In the recovery phase the patients may have less respiratory demand, and therefore a reduction in the pressurisation rate may be more physiological, in order to improve compliance and avoid air leaks.

Many new ventilators are now designed to allow the clinician to set the cycle of criteria at different percentages of the peak flow, while the ventilator used in the current study had a fixed cycling criterion at 5 L·m⁻¹. Therefore, it is possible that different settings of the expiratory cycling for the same pressurisation rate could influence the physiological variables measured in this study.

In conclusion, in this physiological study of severe chronic obstructive pulmonary disease patients recovering from a severe episode of acute hypercapnic respiratory failure necessitating noninvasive pressure support ventilation, a very high pressurisation rate (i.e. 200 cmH₂O·s⁻¹) is associated with increased air leakage and a poor tolerance of ventilation, despite the diaphragmatic effort being reduced. Therefore, the individual titration should be targeted to achieve a good tolerance and minimise the air leaks, keeping a relatively high pressurisation rate. Further studies are needed to assess the influence of different cycle off criteria at different pressurisation rates.