Effects of End-expiratory Positive Pressure Optimization in Intubated Patients With Healthy Lung or Acute Respiratory Distress Syndrome

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Management of ICU patients may require the use of ventilatory support requiring tracheal intubation and invasive mechanical ventilation. Any mechanically ventilated patient is exposed to the formation of atelectasis (collapsed pulmonary alveoli), which occurs systematically after endotracheal tube i...

Management of ICU patients may require the use of ventilatory support requiring tracheal intubation and invasive mechanical ventilation. Any mechanically ventilated patient is exposed to the formation of atelectasis (collapsed pulmonary alveoli), which occurs systematically after endotracheal tube insertion, after any de-recruiting action (tracheal suction, disconnection) or simply if protective ventilation is used, combining small tidal volumes (6 to 8 mL/kg of theoretical ideal body weight - IBW) and an end-expiratory positive pressure (PEEP) that is sometimes insufficient. It is thus proposed to perform alveolar recruitment maneuvers (ARMs), which remove atelectasis by temporarily increasing intrathoracic pressure. To avoid alveolar re-collapse, it is necessary to apply a sufficient level of PEEP. The opening pressure (P) necessary for the re-expansion of a collapsed alveolus is inversely proportional to its radius (r), following Laplace law P = 2.?/r where ? is the surface tension. The pressure necessary to the re-expansion of a collapsed cell depends on its radius. Amato's team has showed in 2006 that within the same lung, several levels of alveolar aeration and thus several opening pressures coexist. The distribution of pressures was bimodal, with a peak around 30 cmH2O and a second around 40 cmH2O. Consequently, to allow complete re-expansion of atelectasis within a lung, it is necessary to apply a pressure at least equal to 30 cmH2O. The application of insufficient pressures cannot be expected to result in complete re-expansion of the lung, but rather in an increase in aeration of already aerated alveoli (whose radius is larger and whose opening pressure is much lower), what, in turn, can lead to over-distension. This is probably what can happen if the PEEP is increased without any previous ARM. The application of an ARM can also lead to an overdistension phenomenon during a reduced period of time (20 to 30 seconds), contrary to the direct application of a high PEEP which could led to an overdistension lasting a much longer period of time (possibly several hours) and aggravated with each administration of a tidal volume (and thus several times per minute). Chronic lung exposure to overdistension phenomena can induce a disintegration of alveolar collagen fibers (volotrauma), leading to local inflammation (biotrauma) and systemic inflammation by releasing pro-inflammatory molecules (cytokines...) into the bloodstream and led to apoptosis in distant organs (kidney, digestive tract for example). The optimization of mechanical ventilation requires the search for the optimal PEEP: insufficient, it cannot prevent atelectasis formation; too high, it would lead to alveolar overdistension. In current practice, the PEEP is determined arbitrary or following a stepwise titration, either by incremental or decremental steps. To date, scientific literature is not unequivocal concerning the use of ARMs and their safety. Thus, some teams prefer not to use ARMs and usually apply an upward PEEP level. The concepts presented above are valid both in patients with healthy lungs and in patients with "sick" lungs, the archetype and most severe form of which is acute respiratory distress syndrome (ARDS), which is a frequent pathology in ICU (10 to 20% of patients admitted). Its definition is based on the Berlin criteria published in 2012. The morality varies between 30 and 40% depending on the severity of the respiratory impairment. Management of patients suffering from ARDS requires an optimization of oxygenation, which is based first of all on mechanical ventilation, whether invasive or not. Since the ARDS Network study published in 2000 in the New England Journal of Medicine, it has been globally accepted that tidal volumes should be reduced to no more than 6 mL/kg IBW. Ventilatory management is based on concepts of "baby lung" and "open lung". These concepts explain that it is mandatory to consider that the lung volume available for mechanical ventilation is very small compared to the healthy lung volume (baby lung) and that the reduction in tidal volume must be accompanied by adjustments to keep the lung "open", combating the formation of atelectasis by the use of sufficient PEEP and ARMs. Far from this pulmonary pathology, any mechanically ventilated patient, whether in the ICU or operating theatre, must benefit from a protective strategy. Any inadequate adjustment of the ventilation parameters can lead to lung lesions induced by mechanical ventilation (VILI, Ventilator Induced Lung Injuries) and to lesions similar to those observed during ARDS. We therefore propose to explore the impact on pulmonary aeration and ventilatory parameters of two different strategies of PEEP optimization during invasive mechanical ventilation in healthy lungs and ARDS ICU patients. This randomized controlled study would allow us to validate our hypotheses, depending on the respiratory mechanics and patient's pulmonary disease.The final aim of this study is to determine the effects of a strategy based on the application of an ARM followed by decremental PEEP titration, compared to an incremental PEEP strategy without ARM, on pulmonary and ventilatory physio-(patho)-logical parameters in ICU patients.

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