Endotracheal intubation is frequently performed in intensive care unit (ICU) patients 1. The endotracheal tube cuff is responsible for tracheal mucosal lesions that are visible at the cuff contact area a few hours after intubation 2345. These lesions may result in serious complications such as tracheal stenosis and tracheal ruptures 678. According to the results of studies using a low-volume, high-pressure endotracheal cuff, the prevalence of postintubation and post-tracheotomy stenosis varies from 10% to 19% in ICU patients 910. More recent studies using a high-volume, low-pressure cuff, however, showed that clinically significant stenosis was less common (1‰–1%) 1112. Hyperinflation of the endotracheal tube cuff is the most frequent risk factor for tracheal ischemia and subsequent complications in these patients 13.

Complications related to insufficient cuff inflation have nevertheless been reported, including leaking of the tidal volume and microaspiration of secretions and subsequent ventilator-associated pneumonia 14. In most ICUs, the endotracheal cuff pressure is never checked 15161718. In these ICUs, caregivers frequently overinflate the tube cuff to prevent gas leak and pulmonary aspiration 1518.

High-volume, low-pressure endotracheal tubes have significantly reduced the frequency of ischemic tracheal lesions. Even when high-volume, low-pressure endotracheal tubes are used, however, ischemic tracheal lesions may occur 19. An endoscopic study performed in 40 patients undergoing surgery showed that obstruction of mucosal blood flow occurred at a lateral wall pressure above 30 cmH₂O 20.

Based on recent recommendations, the cuff pressure should be maintained around 25 cmH₂O in critically ill intubated and mechanically ventilated patients 2114. Although manual measurement of the cuff pressure could reduce overinflation and underinflation frequency, manual measurement may not provide effective control of the cuff pressure. As shown by Duguet and colleagues 22, despite manual control of the endotracheal pressure with a portable manometer according to the French Society of Critical Care Medicine recommendations, the percentage of time the cuff pressure was >30 cmH₂O was 29 ± 25% and the percentage of time the cuff pressure was <15 cmH₂O was 15 ± 17%.

Several devices enabling efficient continuous control of cuff pressure have been recently described 2223. The pneumatic device is a simple mechanical device that continuously maintains the cuff pressure during mechanical ventilation with minimal human resources 22.

We hypothesized that efficient continuous control of the endotracheal cuff pressure using a pneumatic device would reduce tracheal ischemic lesions in piglets ventilated for 48 hours through a high-volume, low-pressure endotracheal tube.

This study was conducted in the experimental intensive care unit at Lille II University. All animals were treated according to the guidelines of the Department of Experimental Research of Lille University and according to the Guide for the Care and Use of Laboratory Animals (NIH Publication Number 93-23, revised 1985).

The mean arterial pressure (100 (85–110) mmHg versus 100 (89–115) mmHg), the diastolic arterial pressure (70 (61–80) mmHg versus 68 (59–78) mmHg) and the heart rate (101 (90–115) beats/min versus 98 (89–112) beats/min) were similar (P > 0.2) in animals with the pneumatic device and in animals without the pneumatic device.

The mean airway pressure was similar in piglets with or without the pneumatic device (11.3 (11–12.5) cmH₂O versus 12.4 (10.4–13.2) cmH₂O, P = 0.5). The cuff pressure was significantly lower in piglets with the pneumatic device than in piglets without the pneumatic device (18.6 (11–19.4) cmH₂O versus 26 (20–56) cmH₂O, P = 0.009). During overinflation periods, the cuff pressure was significantly lower in piglets with the pneumatic device than in piglets without the pneumatic device (23 (20–25) cmH₂O versus 76 (63–82) cmH₂O, P < 0.001). No significant difference was found in the percentage of time spent with a cuff pressure <15 cmH₂O and the percentage of time with a cuff pressure between 30 and 50 cmH₂O. The percentage of time between 15 and 30 cmH₂O cuff pressure, however, was significantly higher in piglets with the pneumatic device than in piglets without the pneumatic device. In addition, the percentage of time >50 cm H₂O cuff pressure was significantly lower in piglets with the pneumatic device than in piglets without the pneumatic device (Table 1).

Macroscopic examination showed no lesions on the tracheal mucosa distal to the endotracheal tube. In all animals, however, hyperemia and hemorrhages were observed at the cuff contact area (Figure 3).

Histological examination showed no difference in tracheal lesions between animals with or without the pneumatic device. Although no lesions were observed in samples taken distally beyond the endotracheal tube, grade I and grade II lesions were observed in all animals in samples taken from the cuff contact area (Table 2). These lesions included deep mucous ulceration, including fibrin and polynuclear cells, squamous metaplasia and intense mucosal inflammation. Neither cartilage lesion nor inflammation expanding to the subcartilaginous tissue was observed (Figures 4 and Figure 5).

In piglets ventilated for 48 hours through a high-volume, low-pressure endotracheal tube, the pneumatic device enabled an effective continuous control of the endotracheal cuff pressure. This effective control of cuff pressure did not, however, result in any difference with regard to tracheal mucosal damage.

Continuous recording of the cuff pressure in study animals confirmed that the pneumatic device was efficient at continuous cuff pressure regulation. The high volume of the pneumatic-device cuff (200 ml) explains how the injection of 50 ml air did not result in endotracheal cuff overinflation in animals with the pneumatic device, since the endotracheal cuff and the pneumatic-device cuff were connected during inflation periods. In a previous prospective study, the efficacy of the pneumatic device in maintaining constant endotracheal cuff pressure was evaluated in nine consecutive mechanically ventilated critically ill patients 22. The cuff pressure was continuously registered for 24 hours during standard care and for 24 hours with the regulatory device. The authors reported a significant reduction in the coefficient of variation of cuff pressure in patients during the period of mechanical ventilation with the pneumatic device. Other devices are available for cuff pressure control 23262728; however, the device used in the present study has the advantage of being extremely simple to use. In addition, it contains no electronics and does not depend on any sort of power supply.

Despite effective control of the cuff pressure with the pneumatic device, no difference was found in tracheal ischemia between animals with the pneumatic device and those without. This observation suggests that continuous control of the cuff pressure is not effective in preventing tracheal wall damage for a short duration (≤ 48 hours) of mechanical ventilation through a high-volume, low-pressure endotracheal tube. The severity of tracheal damage, however, is related to the duration of intubation 20. Further studies should therefore determine whether continuous control of the endotracheal cuff pressure could reduce the severity of tracheal ischemia over a longer duration of mechanical ventilation. One potential explanation for the absence of a relationship between effective control of the endotracheal cuff pressure and tracheal mucosal lesions is the fact that the cuff pressure in piglets without the pneumatic device was relatively low. If a higher cuff pressure had been used in control animals, a histological difference might have been observed. Our study design aimed at mimicking the clinical situation in intubated and mechanically ventilated ICU patients with manual control of the cuff pressure. In most ICU patients, however, the cuff pressure is never checked 1516. This suggests that the cuff pressure was probably lower in control group than in patients without manual control of cuff pressure. Another possible explanation for the absence of significant difference in histological lesions was the short duration (30 min, eight times daily) of hyperinflation periods in our study. In a clinical setting, hyperinflation periods may occur for longer duration, especially when the cuff pressure is never checked.

In a prospective experimental study, Touzot-Jourde and colleagues 29 randomly assigned orotracheally intubated anesthetized horses to an endotracheal cuff pressure of 80–100 cmH₂O or 120 cmH₂O. Although the duration of invasive mechanical ventilation was short (175 ± 15 min), the tracheal damage was found to be more severe and occurred more frequently in the higher cuff pressure group. The cuff pressures used in their study, however, were much higher than those used in our study. In a study performed in patients with short duration of intubation and mechanical ventilation 30, higher cuff pressure was also associated with a significantly higher rate of ischemic tracheal lesions diagnosed by fiberoptic examination.

Large-volume, low-pressure endotracheal tube cuffs are claimed to have a less deleterious effect on tracheal mucosa than high-pressure, low-volume cuffs. Low-pressure cuffs could easily be overinflated, however, to yield pressures that will exceed capillary perfusion pressure resulting in impaired mucosal blood flow. Loeser and colleagues 19 found a much reduced mean depth of erosion in dogs intubated with large-volume, low-pressure cuffed tubes inflated to the clinical seal for periods of 5–7 hours; however, the area of erosion was significantly greater with the large volume cuff. Impairment of tracheal mucosal blood flow is an important factor in tracheal morbidity associated with intubation. Hence it is recommended that a cuff inflation pressure of 30 cmH₂O (22 mmHg) should not be exceeded to prevent tracheal wall damage 20. In a study performed in intubated rabbits, superficial tracheal damage occurred within 15 minutes at lateral wall pressure of 27 cmH₂O. There was partial denuding of the basement membrane with a lateral wall pressure of 68 cmH₂O. At a lateral wall pressure of 136 cmH₂O, damage extended to the basement membrane and mucosal stroma within 15 minutes – and this damage was progressive with time 31. The prone position was used in our study since in pigs, as in sheep or cows, mechanical ventilation in the supine position results in lung atelectasis with severe ventilation/perfusion mismatch after a few hours 32. Whether these results are applicable in animals ventilated in the supine position is unknown. In addition, our results were obtained in healthy piglets. Tracheal lesions could therefore have been more important if animals had prior tracheal inflammation.

Some limitations of our study should be taken into account. First, animals were intubated and mechanically ventilated for only 48 hours. Our results therefore may not be applicable for a longer duration of mechanical ventilation. Second, the small number of animals that were studied is another limitation of the present study. Larger studies with longer exposure of the tracheal mucosa to cuff overinflation could therefore demonstrate a beneficial effect of the pneumatic device in reducing ischemic tracheal lesions. Third, inflation of the endotracheal cuff with 50 ml air may have been excessive as compared with clinical practice. This maneuver, however, aimed to generate high endotracheal cuff pressures, which are difficult to obtain with small volumes of air when high-volume, low-pressure tubes are used. By contrast, using smaller volumes of air is associated with similar cuff pressures when low-volume, high-pressure tubes are used. The high cuff pressures recorded during inflation periods (>70 cmH₂O) in control animals were similar to those used in previous animal studies to evaluate tracheal mucosal lesions 2031. Another reason for the use of such a high volume of air was to test the efficacy of pneumatic device in preventing cuff overinflation.

We conclude that the pneumatic device provides an effective continuous control of the endotracheal cuff pressure in intubated and mechanically ventilated piglets. No difference was found, however, in tracheal mucosal lesions between animals with or without the pneumatic device. Our results suggest that continuous control of the endotracheal cuff pressure within the recommended pressure range does not necessarily prevent tracheal ischemia, at least in piglets ventilated for 48 hours with a high-volume, low-pressure endotracheal tube. Further studies are needed to determine the impact of continuous control of the cuff pressure over a longer duration of mechanical ventilation.

• The pneumatic device provides effective continuous control of endotracheal cuff pressure in intubated and mechanically ventilated piglets.

• No difference was found in tracheal mucosal lesions between animals with or without the pneumatic device.

• Our results suggest that continuous control of endotracheal cuff pressure within the recommended pressure range does not necessarily prevent tracheal ischemia, at least not in piglets ventilated for 48 hours with a high-volume, low-pressure endotracheal tube.

• Further studies are needed to determine the impact of continuous control of the cuff pressure over a longer duration of mechanical ventilation.

ICU = intensive care unit.

The authors declare that they have no competing interests.

SN, AD, TS, and C-HM designed the study. SN and MZ performed the animal experiments. M-CC performed the histological examination. JDJ performed analysis of the cuff and airway pressure recording. SN wrote the manuscript, and all authors participated in its critical revision. SN had full access to all data in the study and had final responsibility for the decision to submit for publication. All authors read and approved the final manuscript.