Endotracheal Tubes Cleaned With a Novel Mechanism for Secretion Removal: A Randomized Controlled Clinical Study

Discussion

This randomized, controlled clinical trial evaluated the efficacy of a device specifically designed to clean the endotracheal tube lumen of airway secretions. We showed that tubes treated with the endOclear were significantly less occluded than controls, as measured by HRCT.

Narrowing of the endotracheal tube due to secretions is usually an underestimated problem.¹⁷ Mucus attached to the inner ETT surface reduces the volume available to air flow,⁵ thereby leading to increased airway resistance¹⁸ and patient's work of breathing (WOB).⁴ In some cases, the gradual luminal narrowing can progress to complete occlusion of the ETT. In prior studies,^19,20 the degree of ETT occlusion was estimated by using acoustic reflectometry and averaged between 10% and 15%. This noninvasive technique indirectly estimates the tube cross-sectional area (CSA), by analysis of sound waves as they propagate throughout the tube. Our group developed and reported on an innovative methodology for the analysis of ETT occlusion based on HRCT imaging.²¹ We detected an average 25% CSA reduction, compared with paired control unused tubes. Imaging data correlated with in vitro measurements of resistance. Moreover, a variable degree of mucus partially occluding the ETT could also be visualized on standard chest CT scans.³ Compared with acoustic reflectometry, our novel assay based on HRCT offers several advantages, including: (1) the direct visualization and quantitation of mucus volume, and (2) a precise definition of the mucus accumulation pattern across the whole ETT length.

Currently, blind suctioning through a small flexible catheter is the most common method to remove secretions from within the ETT.²² This maneuver can injure the tracheal mucosa,²³ decrease lung volume leading to hypoxia,²⁴ trigger cardiac arrhythmias,²⁵ and increase intracranial pressure.²⁶ In addition, the use of blind suctioning has also been associated with further impairment of tracheal mucociliary clearance function²⁷ together with dislodging emboli of pathogens from the ETT biofilm to the lower airway.²⁸ Several novel dedicated medical devices have been developed for the specific purpose of ETT cleaning. Different from suctioning, the aim of these devices is to remove mucus by physically scraping the inner wall of the tube. Among this new generation of cleaning catheters, we found the endOclear to be a safe and effective device in the clinical setting.¹³ Its efficacy, however, had never been tested in a randomized, controlled fashion.

According to our HRCT results, the use of the endOclear device led to a reduced amount of mucus attached to the inner wall of the ETT after extubation. Consequently, tubes in the treatment group had reduced occlusion. Wright et al demonstrated that the ETT alone significantly contributes to total air flow resistance.²⁹ Luminal narrowing due to mucus accumulation further increases resistance, which varies inversely to the fourth power of the tube's radius, according to the Poiseulle equation: where ΔP is the pressure drop, L is the length of the conduit, μ is the fluid viscosity, Q is the flow, and r is the radius. An increased air flow resistance due to luminal narrowing significantly adds to subjects' WOB, as shown in vivo by Heyer et al.³⁰ According to the authors' estimate, a 10% reduction in the ETT cross-sectional area would correspond to a 27% increase in a patient's WOB.³⁰ Subjects receiving pressure-support ventilation, especially if awake and/or during weaning protocols, might considerably benefit from the reduced respiratory load otherwise imposed by accumulated secretions.

Conti et al³¹ tested an “obstruction remover” in 8 mechanically ventilated subjects, showing a significant reduction of in vivo airway resistance, as well as a reduced WOB. In 2003, the Mucus Shaver was developed by Kolobow et al.³² This device, although not commercially available, was shown to be effective in clearing secretions from the ETT first in an animal study,³² followed by a small clinical trial.³³ More recently, Liu et al³⁴ investigated the use of 8F sterile urinary catheters as an easily available alternative to the Shaver in a population of 45 intubated children. Similar to the Shaver, the regular implementation of this ETT cleaning maneuver reduced bacterial colonization and biofilm thickness as determined by confocal microscopy. However, none of these devices are commercially available, and all of these studies lacked accurate measurements of ETT patency.

In our study, we also tested the hypothesis that, by mechanically scraping the ETT inner surface, the use of the endOclear could interfere with the process of biofilm formation, therefore delaying colonization by clinically relevant pathogens. To test this secondary end point, we categorized bacterial isolates as “VAP causatives,” according to a retrospective analysis of VAP microbial etiology conducted at our institution.¹⁵ In this work by Arvanitis et al, 208 VAP cases over a 5-y period were identified by searching a large hospital infection control database (approximately 40 VAP cases/year). Nevertheless, we did not find any significant difference in the rate of ETT colonization between the 2 groups. Among our selected population of intubated subjects, we registered a total of only 7 clinically diagnosed VAP cases over 6 months. Focusing on the ETT microbial colonization by Gram-negative VAP-causative agents, we isolated such bacteria in 7 treated ETTs versus 15 controls, meaning a 50% relative reduction in the risk of isolating such pathogens in cleaned tubes. However, it is likely that this trend did not reach statistical significance due to the small sample size. Alternatively, the use of a cleaning device might not be effective by itself in limiting the process of biofilm formation. We are currently exploring whether there is a synergic effect between ETT cleaning with the endOclear and the use of an antibacterial coating on the ETT lumen to reduce biofilm formation in the ETT (ClinicalTrials.gov NCT#02120001).

Throughout our study enrollment, the endOclear was safely used, with no adverse events reported over several ETT cleaning maneuvers. However, albeit unlikely, ETT displacement and tracheal injury must still be considered as potential risks associated with the use of the device. We believe the careful application of the available safety measures (red toggle, centimeter markings, blue safety stop) will significantly reduce the likelihood of such complications.

This study has several limitations. First, the enrollment design did not control ETT size. Ideally, to avoid any confounding factors, enrolled subjects should have been intubated with same-sized, same-brand tubes, or at least a size-balanced randomization should have been implemented. Second, in a trial involving 5 heterogeneous ICUs, no unit-based randomization was planned to limit possible confounders related to the type of admission. However, despite a slight imbalance in subjects being intubated due to respiratory failure, no significant baseline differences were recorded between the 2 groups. Third, no blinding of the respiratory therapists performing the study treatment could physically be applied, potentially leading to a bias due to the staff being more scrupulous when using the new device compared with usual care. Fourth, our study protocol did not include any restrictions on the institutional practice for tracheal suctioning. The aim of the study was to test the efficacy of routine ETT cleaning with a dedicated device in addition to the standard of care. However, a different rate of suctioning between the groups, although unlikely, could have altered our findings. Finally, this is a phase 2 randomized clinical trial to establish the effectiveness of cleaning of the lumen of the ETT; therefore, no conclusions can be drawn regarding major clinical outcomes.

Larger studies are needed in order to establish the role of ETT cleaning in terms of reducing time on the ventilator, length of ICU stay, and VAP incidence. Additionally, technical features must be developed and tested to improve the functionality of cleaning devices and promote their routine use. At our institution, the use of the endOclear was adequately implemented with no adverse events reported, and the respiratory therapists involved in the protocol positively reviewed the device. The endOclear is a first-generation product that still requires disconnection of the patient from the mechanical ventilator. A promising solution would be to implement such cleaning apparatus on a closed suction system, to avoid repeated disruptions of the breathing circuit.