Static and Dynamic Transpulmonary Driving Pressures Affect Lung and Diaphragm Injury during Pressure-controlled <i>versus</i> Pressure-support Ventilation in Experimental Mild Lung Injury in Rats

Pinto, Eliete Ferreira; Santos, Rodrigues dos; Antunes, Mariana A.; Maia, Lígia A.; Padilha, Gisele A.; Machado, Joana de A.; Carvalho, Ana Karine Furtado de; Fernandes, Marcos V. S.; Capelozzi, Vera Luíza; Abreu, Marcelo Gama de; Pelosi, Paolo; Rocco, Patrícia Rieken Macêdo; Silva, Pedro L.

doi:10.1097/aln.0000000000003060

Cited by 20 publications

(25 citation statements)

References 45 publications

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“…Due to the shortage of ICU beds during the pandemic, 35 a relatively high number of patients were treated with non-invasive respiratory support for many days even when their clinical status would have required intubation and invasive mechanical ventilation, which may have led to P-SILI. In COVID-19, four potential mechanisms of P-SILI may be suggested: 1) increased lung stress/strain, 36 , 37 , 38 , 39 2) inhomogeneous distribution of ventilation, 4 40 3 ) changes in lung perfusion, 16 23 and 4) patient-ventilator asynchronies during non-invasive positive pressure ventilation (NPPV). 41 42 Increased lung stress/strain …”

Section: Mechanisms Of P-silimentioning

confidence: 99%

Noninvasive respiratory support and patient self-inflicted lung injury in COVID-19: a narrative review

Battaglini

Robba

Ball

et al. 2021

British Journal of Anaesthesia

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Coronavirus disease 2019 (COVID-19) pneumonia is associated with hypoxemic respiratory failure, ranging from mild to severe. Due to the worldwide shortage of intensive care unit beds, a relatively high number of patients with respiratory failure are receiving prolonged non-invasive respiratory support, even when their clinical status would have required invasive mechanical ventilation. There are few experimental and clinical data reporting that vigorous breathing effort during spontaneous ventilation can worsen lung injury and cause a phenomenon that has been termed patient self-inflicted lung injury (P-SILI). The aim of this narrative review is to provide an overview of P-SILI pathophysiology and the role of non-invasive respiratory support in COVID-19 pneumonia. Respiratory mechanics, vascular compromise, viscoelastic properties, lung inhomogeneity, work of breathing, and oesophageal pressure swings are discussed. The concept of P-SILI has been widely investigated in recent years, but controversies persist regarding its mechanisms. To minimize the risk of P-SILI, intensivists should better understand its underlying pathophysiology to optimize the type of non-invasive respiratory support provided to patients with COVID-19 pneumonia, as well as decide on the optimal timing of intubation for these patients.

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Section: Mechanisms Of P-silimentioning

confidence: 99%

Noninvasive respiratory support and patient self-inflicted lung injury in COVID-19: a narrative review

Battaglini

Robba

Ball

et al. 2021

British Journal of Anaesthesia

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“…ARDS requires, indeed, more precise fine-tuned ventilation, since the wide and unpredictable characteristics of the disease, especially the amount of alveolar and interstitial edema, make it difficult to develop a standard that fits all the patients and conditions. Personalizing mechanical ventilation in patients affected by ARDS aims to keep under control different variables, each one affecting the different components of VILI pathophysiology (Nieman et al, 2017 ; Tonetti et al, 2017 ; Pinto et al, 2020 ). DP L is the pressure to which the lung parenchyma is cyclically exposed during tidal breathing and represents the stress applied to the lung, not considering the pressure needed to overcome the chest-wall resistance.…”

Section: Discussionmentioning

confidence: 99%

Calculation of Transpulmonary Pressure From Regional Ventilation Displayed by Electrical Impedance Tomography in Acute Respiratory Distress Syndrome

et al. 2021

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Transpulmonary driving pressure (DPL) corresponds to the cyclical stress imposed on the lung parenchyma during tidal breathing and, therefore, can be used to assess the risk of ventilator-induced lung injury (VILI). Its measurement at the bedside requires the use of esophageal pressure (Peso), which is sometimes technically challenging. Recently, it has been demonstrated how in an animal model of ARDS, the transpulmonary pressure (PL) measured with Peso calculated with the absolute values method (PL = Paw—Peso) is equivalent to the transpulmonary pressure directly measured using pleural sensors in the central-dependent part of the lung. We hypothesized that, since the PL derived from Peso reflects the regional behavior of the lung, it could exist a relationship between regional parameters measured by electrical impedance tomography (EIT) and driving PL (DPL). Moreover, we explored if, by integrating airways pressure data and EIT data, it could be possible to estimate non-invasively DPL and consequently lung elastance (EL) and elastance-derived inspiratory PL (PI). We analyzed 59 measurements from 20 patients with ARDS. There was a significant intra-patient correlation between EIT derived regional compliance in regions of interest (ROI1) (r = 0.5, p = 0.001), ROI2 (r = −0.68, p < 0.001), and ROI3 (r = −0.4, p = 0.002), and DPL. A multiple linear regression successfully predicted DPL based on respiratory system elastance (Ers), ideal body weight (IBW), roi1%, roi2%, and roi3% (R2 = 0.84, p < 0.001). The corresponding Bland-Altmann analysis showed a bias of −1.4e-007 cmH2O and limits of agreement (LoA) of −2.4–2.4 cmH2O. EL and PI calculated using EIT showed good agreement (R2 = 0.89, p < 0.001 and R2 = 0.75, p < 0.001) with the esophageal derived correspondent variables. In conclusion, DPL has a good correlation with EIT-derived parameters in the central lung. DPL, PI, and EL can be estimated with good accuracy non-invasively combining information coming from EIT and airway pressure.

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“…Due to limited availability of ICU beds, a relatively high number of patients were treated with noninvasive respiratory support for many days, which may lead to P-SILI. Four potential mechanisms of P-SILI in COVID-19 have been suggested: (1) increased lung stress/strain, 85 (2) inhomogeneous distribution of ventilation, 82 (3) changes in lung perfusion, 86 and (4) patient–ventilator asynchronies during noninvasive positive-pressure ventilation. 87…”

Section: Ventilator-induced Lung Injurymentioning

confidence: 99%

Physiological and Pathophysiological Consequences of Mechanical Ventilation

Silva

Ball

Rocco

et al. 2022

Semin Respir Crit Care Med

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Mechanical ventilation is a life-support system used to ensure blood gas exchange and to assist the respiratory muscles in ventilating the lung during the acute phase of lung disease or following surgery. Positive-pressure mechanical ventilation differs considerably from normal physiologic breathing. This may lead to several negative physiological consequences, both on the lungs and on peripheral organs. First, hemodynamic changes can affect cardiovascular performance, cerebral perfusion pressure (CPP), and drainage of renal veins. Second, the negative effect of mechanical ventilation (compression stress) on the alveolar-capillary membrane and extracellular matrix may cause local and systemic inflammation, promoting lung and peripheral-organ injury. Third, intra-abdominal hypertension may further impair lung and peripheral-organ function during controlled and assisted ventilation. Mechanical ventilation should be optimized and personalized in each patient according to individual clinical needs. Multiple parameters must be adjusted appropriately to minimize ventilator-induced lung injury (VILI), including: inspiratory stress (the respiratory system inspiratory plateau pressure); dynamic strain (the ratio between tidal volume and the end-expiratory lung volume, or inspiratory capacity); static strain (the end-expiratory lung volume determined by positive end-expiratory pressure [PEEP]); driving pressure (the difference between the respiratory system inspiratory plateau pressure and PEEP); and mechanical power (the amount of mechanical energy imparted as a function of respiratory rate). More recently, patient self-inflicted lung injury (P-SILI) has been proposed as a potential mechanism promoting VILI. In the present chapter, we will discuss the physiological and pathophysiological consequences of mechanical ventilation and how to personalize mechanical ventilation parameters.

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Static and Dynamic Transpulmonary Driving Pressures Affect Lung and Diaphragm Injury during Pressure-controlled versus Pressure-support Ventilation in Experimental Mild Lung Injury in Rats

Cited by 20 publications

References 45 publications

Noninvasive respiratory support and patient self-inflicted lung injury in COVID-19: a narrative review

Noninvasive respiratory support and patient self-inflicted lung injury in COVID-19: a narrative review

Calculation of Transpulmonary Pressure From Regional Ventilation Displayed by Electrical Impedance Tomography in Acute Respiratory Distress Syndrome

Physiological and Pathophysiological Consequences of Mechanical Ventilation

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