![]() ![]() tends to underestimate alveolar recruitment.adjust PEEP to maximise static compliance (Cstat) (increased risk of alveolar stretch above this).likely insignificant SI increased intracranial pressure (ICP) (due to increased intrathoracic pressure).causes liver congestion and LFT changes.decreased hepatic artery and portal venous flow (due to increased intrathoracic pressure).exacerbation of right-to-left intracardiac shunt (if present).in focal ARDS, less likely if Pplat Pa >Pv) overinflation of non-dependent alveoli (e.g.if decreased tidal volume due to lower driving pressure or poor compliance due to alveolar over-distention.impaired carbon dioxide (CO2) elimination.decreased preload and work of breathing also help in acute pulmonary oedema.decrease in left ventricular (LV) afterload (due to decreased LV transmural pressure).decreased inflammatory response to mechanical ventilation.prevention of surfactant aggregation reducing alveolar collapse.decreased work of breathing (less effort to trigger inspiration in spontaneous ventilation modes as alveolar pressure only needs to decrease to the level of PEEP for inspiration to occur).decreased ventilation/perfusion (V/Q) mismatch and shunt fraction.improved lung compliance (inspiration begins on a steeper portion of the volume-pressure curve).decreases biotrauma from alveolar collapse (e.g.prevents cyclic de-recruitment on expiration (decreases atelectrauma and VILI).minimises denitrogenation atelectasis and oxygen toxicity (by allowing lower FiO2).extra-vascular lung water (EVLW) may be displaced from alveolar interstitium to peribronchial interstitium.increased capillary-alveoli interface for gas exchange.increase arterial oxygen tension (PaO2).increased functional residual capacity (FRC) (prevention of airway and alveolar collapse).increased airway pressure (improves oxygenation and alveolar recruitment).also termed “occult PEEP” by as PEEPi is not apparent on proximal airway pressure recordings (Pepe & Marini, Marino, 2013).less likely to be uniformly distributed than PEEPe.due to insufficient expiratory time (Te), typically in the presence of severe air-flow obstruction (e.g.elevation in the static recoil pressure of the lungs above the set PEEPe at end expiration.a solenoid valve is commonly used in ventilators.a threshold resistor is preferred, as resistance to flow is minimal once threshold pressure is reached. ![]() In spontaneous ventilation using non-invasive ventilation (NIV), CPAP (continuous positive airway pressure) is analogous to PEEP, but the pressure applied is maintained throughout the respiratory cycle (during both inspiration and expiration).Įxtrinsic PEEP (PEEPe) is applied by placing resistance in the expiratory limb of a ventilator circuit.“High” PEEP is used as part of an Open Lung Approach To Ventilation for Acute Respiratory Distress Syndrome (ARDS).How to optimise PEEP is a controversial topic, but should involve (1) optimisation of oxygenation and (2) minimisation of ventilator induced lung injury (VILI), and should should be individualised for a given patient.PEEP is routinely used in mechanical ventilation to prevent collapse of distal alveoli, and to promote recruitment of collapsed alveoli.PEEP acts to distend distal alveoli, assuming there is no airway obstruction. Positive End-Expiratory Pressure (PEEP) is the maintenance of positive pressure (above atmospheric) at the airway opening at the end of expiration. ![]()
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