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Patient self‑inflicted lung injury

Artikel

Autor: Munir Karjaghli

Datum: 11.05.2020

Facilitating spontaneous efforts in those patients under light sedation is an important part of mechanical ventilation in the ICU.
Patient self-inflicted lung injury

Takeaway messages

  • Experimental and clinical data show that spontaneous effort is difficult to control within a safe range when lung injury is more severe, and strong spontaneous effort may worsen lung injury.
  • The concept of “ventilation”‑induced lung injury covers lung injury occuring from overdistension caused either by the mechanical ventilator (VILI) or the patient’s own breathing (P‑SILI).
  • Recent experimental and clinical studies indicate that higher levels of PEEP may result in less injurious spontaneous efforts in patients with moderate to severe ARDS.

What is P‑SILI?

On the one hand, assisting these efforts can bring various benefits to the patients, such as better gas exchange, maintenance of peripheral muscles, and diaphragm function. On the other hand, it may also be associated with a deterioration in oxygenation (Coggeshall JW, Marini JJ, Newman JH. Improved oxygenation after muscle relaxation in adult respiratory distress syndrome. Arch Intern Med. 1985;145(9):1718‑1720. 1​) as well as cause lung injury (Mascheroni D, Kolobow T, Fumagalli R, Moretti MP, Chen V, Buckhold D. Acute respiratory failure following pharmacologically induced hyperventilation: an experimental animal study. Intensive Care Med. 1988;15(1):8‑14. doi:10.1007/BF002556282​). This conflict has led to extensive discussions about the potential risk of spontaneous effort during mechanical ventilation and how this risk may be avoided (Güldner A, Pelosi P, Gama de Abreu M. Spontaneous breathing in mild and moderate versus severe acute respiratory distress syndrome. Curr Opin Crit Care. 2014;20(1):69‑76. doi:10.1097/MCC.00000000000000553​, Yoshida T, Fujino Y, Amato MB, Kavanagh BP. Fifty Years of Research in ARDS. Spontaneous Breathing during Mechanical Ventilation. Risks, Mechanisms, and Management. Am J Respir Crit Care Med. 2017;195(8):985‑992. doi:10.1164/rccm.201604‑0748CP4​).  In 2017, the term “patient self‑inflicted lung injury” (P‑SILI) was coined to describe effort‑dependent lung injury. Although the concept of P‑SILI is relatively new, the underlying mechanism of P‑SILI is similar to that of VILI (Yoshida T, Fujino Y, Amato MB, Kavanagh BP. Fifty Years of Research in ARDS. Spontaneous Breathing during Mechanical Ventilation. Risks, Mechanisms, and Management. Am J Respir Crit Care Med. 2017;195(8):985-992. doi:10.1164/rccm.201604-0748CP4​, Bellani G, Grasselli G, Teggia-Droghi M, et al. Do spontaneous and mechanical breathing have similar effects on average transpulmonary and alveolar pressure? A clinical crossover study. Crit Care. 2016;20(1):142. Published 2016 Apr 28. doi:10.1186/s13054-016-1290-95​). In the case of P-SILI, the patient’s own spontaneous effort (i.e., negative pleural pressure) causes global and local overdistension, which is then exacerbated to a degree by the ventilator. A recent publication by Yoshida et al. (Yoshida T, Grieco DL, Brochard L, Fujino Y. Patient self-inflicted lung injury and positive end-expiratory pressure for safe spontaneous breathing. Curr Opin Crit Care. 2020;26(1):59-65. doi:10.1097/MCC.00000000000006916​) looked more closely at the causes of P-SILI, as well as the use of higher PEEP for safe spontaneous breathing.

Mechanisms of patient self‑inflicted lung injury (P‑SILI)

There are three mechanisms by which spontaneous effort may potentially cause lung injury: global and local overdistension, increased lung perfusion, and patient‑ventilator asynchrony.

1. Overdistension

During pressure assist‑control or pressure support ventilation, spontaneous breathing reduces pleural pressure (Ppl), while transpulmonary pressure (PL) and tidal volume (VT) will be increased. Global overdistension reflected by high PL, can then exacerbate lung injury, caused by either the mechanical ventilator or the patient’s effort, or both. A result of strong efforts are negative local ‘swings’ in Ppl; these are observed more in the dependent lung than in the rest of the lung (Yoshida T, Torsani V, Gomes S, et al. Spontaneous effort causes occult pendelluft during mechanical ventilation. Am J Respir Crit Care Med. 2013;188(12):1420-1427. doi:10.1164/rccm.201303-0539OC7​). The higher local (dependent) lung stress then leads to local overdistension. In addition, it also causes considerable tidal recruitment and decruitment at expiration in the dependent lung, by drawing gas from other lung regions (e.g., the nondependent lung). Recent data has confirmed that the majority of effort-dependent lung injury occurs in the dependent lung, that is, the same region in which strong effort caused greater inspiratory stress and stretch (Morais CCA, Koyama Y, Yoshida T, et al. High Positive End-Expiratory Pressure Renders Spontaneous Effort Noninjurious. Am J Respir Crit Care Med. 2018;197(10):1285-1296. doi:10.1164/rccm.201706-1244OC8​).

2. Increased lung perfusion

The more negative Ppl, generated by spontaneous effort leads to increased transmural vascular pressure, the net pressure distending the intrathoracic vessels. In fact, strong spontaneous effort during volume‑controlled low VT ventilation can generate such negative Ppl that ARDS patients may suffer from pulmonary edema (Kallet RH, Alonso JA, Luce JM, Matthay MA. Exacerbation of acute pulmonary edema during assisted mechanical ventilation using a low-tidal volume, lung-protective ventilator strategy. Chest. 1999;116(6):1826-1832. doi:10.1378/chest.116.6.18269​). Recently, strong spontaneous effort has also been shown to increase lung perfusion and a tendency to edema, as well as have a negative impact on outcomes in children with acute exacerbations of asthma (Kantor DB, Hirshberg EL, McDonald MC, et al. Fluid Balance Is Associated with Clinical Outcomes and Extravascular Lung Water in Children with Acute Asthma Exacerbation. Am J Respir Crit Care Med. 2018;197(9):1128-1135. doi:10.1164/rccm.201709-1860OC10​).

3. Patient‑ventilator asynchrony

Asynchrony can potentially worsen lung injury, and data from 50 ventilated patients suggests an association with higher mortality (Blanch L, Villagra A, Sales B, et al. Asynchronies during mechanical ventilation are associated with mortality. Intensive Care Med. 2015;41(4):633‑641. doi:10.1007/s00134‑015‑3692‑611​). Double triggering, for example, is potentially injurious because of the high VT delivered to the patient. This form of asynchrony is more common in patients with a higher respiratory drive, which is easy to detect and widely recognized to be harmful. Reverse triggering, on the other hand, can occur in heavily sedated patients where the risk of asynchrony is considered to be low. Reverse triggering can result in increased PL and/or VT, and through pendelluft may also increase dependent‑lung stress and stretch.

PEEP for safe spontaneous breathing

Higher PEEP may be effective in reducing lung injury from spontaneous efforts. Earlier publications showed that ∆Pes or Ppl following phrenic nerve stimulation is minimized, as the end‑expiratory lung volume is increased. This is a phenomenon observed consistently in both normal animal and human lungs (Laghi F, Harrison MJ, Tobin MJ. Comparison of magnetic and electrical phrenic nerve stimulation in assessment of diaphragmatic contractility. J Appl Physiol (1985). 1996;80(5):1731-1742. doi:10.1152/jappl.1996.80.5.173112​). More recently, the same observation has been confirmed in an ARDS model (rabbits and pigs). Higher PEEP - and thus higher end-expiratory lung volume - was associated with less spontaneous effort (estimated by ∆Pes or ∆Ppl), and reduced P-SILI (Kiss T, Bluth T, Braune A, et al. Effects of Positive End-Expiratory Pressure and Spontaneous Breathing Activity on Regional Lung Inflammation in Experimental Acute Respiratory Distress Syndrome. Crit Care Med. 2019;47(4):e358-e365. doi:10.1097/CCM.000000000000364913​). The most recent randomized clinical trial to re-evaluate systemic early neuromuscular blockade in moderate to severe ARDS (ROSE trial) provides indirect support for the argument that higher PEEP may render spontaneous effort less injurious (National Heart, Lung, and Blood Institute PETAL Clinical Trials Network, Moss M, Huang DT, et al. Early Neuromuscular Blockade in the Acute Respiratory Distress Syndrome. N Engl J Med. 2019;380(21):1997-2008. doi:10.1056/NEJMoa190168614​).

Mechanism for higher positive end‑expiratory pressure

  • Higher PEEP can reduce the amount of atelectatic lung, which can lead to a more homogeneous distribution of ∆Ppl over the whole lung surface. This helps avoid local overdistension in dependent lung regions.
  • Higher PEEP may help to decrease those forces generated by spontaneous efforts (reflected by ∆Pes or ∆Ppl) in ARDS patients.
  • Higher PEEP often improves gas exchange, which in turn may help to reduce respiratory drive.
  • External PEEP may act as a counterbalancing force and minimize the pressure differences across the small airways, reducing the effort to trigger the ventilator and the increased load of inspiratory muscles (Rossi A, Brandolese R, Milic‑Emili J, Gottfried SB. The role of PEEP in patients with chronic obstructive pulmonary disease during assisted ventilation. Eur Respir J. 1990;3(7):818‑822. 15​).

Conclusion

Lung injury in mechanically ventilated patients occurs due to overdistension caused by either the ventilator or the patient’s own breathing, or both. In moderate to severe ARDS, higher levels of PEEP may allow “safe” spontanous breathing and therefore help prevent P‑SILI.

Ventilators from Hamilton Medical offer a range of tools and features that not only enable clinicians to monitor the patient’s effort, but to customize ventilation therapy to each individual patient. You are able to measure and display esophageal and transpulmonary pressures in spontaneously breathing patients, monitor lung protection, and assess patient‑ventilator interaction. IntelliSync+( Nicht für alle Märkte verfügbar.A​) allows continuous monitoring of ventilated patients and/or improved breath triggering and cycling.

Fußnoten

  • A. Nicht für alle Märkte verfügbar.

Referenzen

  1. 1. Coggeshall JW, Marini JJ, Newman JH. Improved oxygenation after muscle relaxation in adult respiratory distress syndrome. Arch Intern Med. 1985;145(9):1718‑1720.
  2. 2. Mascheroni D, Kolobow T, Fumagalli R, Moretti MP, Chen V, Buckhold D. Acute respiratory failure following pharmacologically induced hyperventilation: an experimental animal study. Intensive Care Med. 1988;15(1):8‑14. doi:10.1007/BF00255628
  3. 3. Güldner A, Pelosi P, Gama de Abreu M. Spontaneous breathing in mild and moderate versus severe acute respiratory distress syndrome. Curr Opin Crit Care. 2014;20(1):69‑76. doi:10.1097/MCC.0000000000000055
  4. 4. Yoshida T, Fujino Y, Amato MB, Kavanagh BP. Fifty Years of Research in ARDS. Spontaneous Breathing during Mechanical Ventilation. Risks, Mechanisms, and Management. Am J Respir Crit Care Med. 2017;195(8):985‑992. doi:10.1164/rccm.201604‑0748CP
  5. 5. Bellani G, Grasselli G, Teggia‑Droghi M, et al. Do spontaneous and mechanical breathing have similar effects on average transpulmonary and alveolar pressure? A clinical crossover study. Crit Care. 2016;20(1):142. Published 2016 Apr 28. doi:10.1186/s13054‑016‑1290‑9
  6. 6. Yoshida T, Grieco DL, Brochard L, Fujino Y. Patient self‑inflicted lung injury and positive end‑expiratory pressure for safe spontaneous breathing. Curr Opin Crit Care. 2020;26(1):59‑65. doi:10.1097/MCC.0000000000000691
  7. 7. Yoshida T, Torsani V, Gomes S, et al. Spontaneous effort causes occult pendelluft during mechanical ventilation. Am J Respir Crit Care Med. 2013;188(12):1420‑1427. doi:10.1164/rccm.201303‑0539OC
  8. 8. Morais CCA, Koyama Y, Yoshida T, et al. High Positive End‑Expiratory Pressure Renders Spontaneous Effort Noninjurious. Am J Respir Crit Care Med. 2018;197(10):1285‑1296. doi:10.1164/rccm.201706‑1244OC
  9. 9. Kallet RH, Alonso JA, Luce JM, Matthay MA. Exacerbation of acute pulmonary edema during assisted mechanical ventilation using a low‑tidal volume, lung‑protective ventilator strategy. Chest. 1999;116(6):1826‑1832. doi:10.1378/chest.116.6.1826
  10. 10. Kantor DB, Hirshberg EL, McDonald MC, et al. Fluid Balance Is Associated with Clinical Outcomes and Extravascular Lung Water in Children with Acute Asthma Exacerbation. Am J Respir Crit Care Med. 2018;197(9):1128‑1135. doi:10.1164/rccm.201709‑1860OC
  11. 11. Blanch L, Villagra A, Sales B, et al. Asynchronies during mechanical ventilation are associated with mortality. Intensive Care Med. 2015;41(4):633‑641. doi:10.1007/s00134‑015‑3692‑6
  12. 12. Laghi F, Harrison MJ, Tobin MJ. Comparison of magnetic and electrical phrenic nerve stimulation in assessment of diaphragmatic contractility. J Appl Physiol (1985). 1996;80(5):1731‑1742. doi:10.1152/jappl.1996.80.5.1731
  13. 13. Kiss T, Bluth T, Braune A, et al. Effects of Positive End‑Expiratory Pressure and Spontaneous Breathing Activity on Regional Lung Inflammation in Experimental Acute Respiratory Distress Syndrome. Crit Care Med. 2019;47(4):e358‑e365. doi:10.1097/CCM.0000000000003649
  14. 14. National Heart, Lung, and Blood Institute PETAL Clinical Trials Network, Moss M, Huang DT, et al. Early Neuromuscular Blockade in the Acute Respiratory Distress Syndrome. N Engl J Med. 2019;380(21):1997‑2008. doi:10.1056/NEJMoa1901686
  15. 15. Rossi A, Brandolese R, Milic‑Emili J, Gottfried SB. The role of PEEP in patients with chronic obstructive pulmonary disease during assisted ventilation. Eur Respir J. 1990;3(7):818‑822.

Improved oxygenation after muscle relaxation in adult respiratory distress syndrome.

Coggeshall JW, Marini JJ, Newman JH. Improved oxygenation after muscle relaxation in adult respiratory distress syndrome. Arch Intern Med. 1985;145(9):1718‑1720.

Arterial blood oxygenation improved repeatedly after sedation and paralysis in a 27‑year‑old woman requiring mechanical ventilation for the adult respiratory distress syndrome. Oxygen consumption and cardiac output decreased proportionately after paralysis so that the partial pressure of oxygen in mixed venous blood remained unchanged. Paralysis eliminated inspiratory distortion of the airway pressure waveform and prevented forceful use of expiratory musculature. A flow‑related reduction of venous admixture or recruitment of lung volume may best explain the beneficial effect of muscle relaxation on arterial saturation.

Acute respiratory failure following pharmacologically induced hyperventilation: an experimental animal study.

Mascheroni D, Kolobow T, Fumagalli R, Moretti MP, Chen V, Buckhold D. Acute respiratory failure following pharmacologically induced hyperventilation: an experimental animal study. Intensive Care Med. 1988;15(1):8‑14. doi:10.1007/BF00255628

The pulmonary effects of hyperventilation following infusion of sodium salicylate into the cisterna magna was studied in 16 spontaneously breathing adult sheep. We found a fall in PaO2, a decrease in the static compliance of the respiratory system, abnormal chest roentgenographic films, and grossly abnormal lungs following 3.5 to 13 h of hyperventilation. A control group of 15 sheep (10 sheep similarly injected with sodium salicylate, but then sedated and paralyzed and ventilated at normal tidal volume and respiratory rate on a mechanical ventilator, and 5 sheep infused with saline alone and breathing spontaneously) showed no pulmonary or arterial blood gas abnormalities. We conclude that prolonged hyperventilation under the conditions of this experiment precipitated events that resulted in acute lung injury.

Spontaneous breathing in mild and moderate versus severe acute respiratory distress syndrome.

Güldner A, Pelosi P, Gama de Abreu M. Spontaneous breathing in mild and moderate versus severe acute respiratory distress syndrome. Curr Opin Crit Care. 2014;20(1):69‑76. doi:10.1097/MCC.0000000000000055



PURPOSE OF REVIEW

This review summarizes the most recent clinical and experimental data on the impact of spontaneous breathing in acute respiratory distress syndrome (ARDS).

RECENT FINDINGS

Spontaneous breathing during assisted as well as nonassisted modes of mechanical ventilation improves lung function and reduces lung damage in mild and moderate ARDS. New modes of assisted mechanical ventilation with improved patient ventilator interaction and enhanced variability of the respiratory pattern offer additional benefit on lung function and damage. However, data supporting an outcome benefit of spontaneous breathing in ARDS, even in its mild and moderate forms, are missing. In contrast, controlled mechanical ventilation with muscle paralysis in the first 48 h of severe ARDS has been shown to improve survival, as compared with placebo. Currently, it is unclear whether ventilator settings, rather than the severity of lung injury, determine the potential of spontaneous breathing for benefit or harm.

SUMMARY

Clinical and experimental studies show that controlled mechanical ventilation with muscle paralysis in the early phase of severe ARDS reduces lung injury and even mortality. At present, spontaneous breathing should be avoided in the early phase of severe ARDS, but considered in mild‑to‑moderate ARDS.

Fifty Years of Research in ARDS. Spontaneous Breathing during Mechanical Ventilation. Risks, Mechanisms, and Management.

Yoshida T, Fujino Y, Amato MB, Kavanagh BP. Fifty Years of Research in ARDS. Spontaneous Breathing during Mechanical Ventilation. Risks, Mechanisms, and Management. Am J Respir Crit Care Med. 2017;195(8):985‑992. doi:10.1164/rccm.201604‑0748CP

Spontaneous respiratory effort during mechanical ventilation has long been recognized to improve oxygenation, and because oxygenation is a key management target, such effort may seem beneficial. Also, disuse and loss of peripheral muscle and diaphragm function is increasingly recognized, and thus spontaneous breathing may confer additional advantage. Reflecting this, epidemiologic data suggest that the use of partial (vs. full) support modes of ventilation is increasing. Notwithstanding the central place of spontaneous breathing in mechanical ventilation, accumulating evidence indicates that it may cause‑or worsen‑acute lung injury, especially if acute respiratory distress syndrome is severe and spontaneous effort is vigorous. This Perspective reviews the evidence for this phenomenon, explores mechanisms of injury, and provides suggestions for clinical management and future research.

Do spontaneous and mechanical breathing have similar effects on average transpulmonary and alveolar pressure? A clinical crossover study.

Bellani G, Grasselli G, Teggia‑Droghi M, et al. Do spontaneous and mechanical breathing have similar effects on average transpulmonary and alveolar pressure? A clinical crossover study. Crit Care. 2016;20(1):142. Published 2016 Apr 28. doi:10.1186/s13054‑016‑1290‑9



BACKGROUND

Preservation of spontaneous breathing (SB) is sometimes debated because it has potentially both negative and positive effects on lung injury in comparison with fully controlled mechanical ventilation (CMV). We wanted (1) to verify in mechanically ventilated patients if the change in transpulmonary pressure was similar between pressure support ventilation (PSV) and CMV for a similar tidal volume, (2) to estimate the influence of SB on alveolar pressure (Palv), and (3) to determine whether a reliable plateau pressure could be measured during pressure support ventilation (PSV).

METHODS

We studied ten patients equipped with esophageal catheters undergoing three levels of PSV followed by a phase of CMV. For each condition, we calculated the maximal and mean transpulmonary (ΔPL) swings and Palv.

RESULTS

Overall, ΔPL was similar between CMV and PSV, but only loosely correlated. The differences in ΔPL between CMV and PSV were explained largely by different inspiratory flows, indicating that the resistive pressure drop caused this difference. By contrast, the Palv profile was very different between CMV and SB; SB led to progressively more negative Palv during inspiration, and Palv became lower than the set positive end‑expiratory pressure in nine of ten patients at low PSV. Finally, inspiratory occlusion holds performed during PSV led to plateau and Δ PL pressures comparable with those measured during CMV.

CONCLUSIONS

Under similar conditions of flow and volume, transpulmonary pressure change is similar between CMV and PSV. SB during mechanical ventilation can cause remarkably negative swings in Palv, a mechanism by which SB might potentially induce lung injury.

Patient self‑inflicted lung injury and positive end‑expiratory pressure for safe spontaneous breathing.

Yoshida T, Grieco DL, Brochard L, Fujino Y. Patient self‑inflicted lung injury and positive end‑expiratory pressure for safe spontaneous breathing. Curr Opin Crit Care. 2020;26(1):59‑65. doi:10.1097/MCC.0000000000000691



PURPOSE OF REVIEW

The potential risks of spontaneous effort and their prevention during mechanical ventilation is an important concept for clinicians and patients. The effort‑dependent lung injury has been termed 'patient self‑inflicted lung injury (P‑SILI)' in 2017. As one of the potential strategies to render spontaneous effort less injurious in severe acute respiratory distress syndrome (ARDS), the role of positive end‑expiratory pressure (PEEP) is now discussed.

RECENT FINDINGS

Experimental and clinical data indicate that vigorous spontaneous effort may worsen lung injury, whereas, at the same time, the intensity of spontaneous effort seems difficult to control when lung injury is severe. Experimental studies found that higher PEEP strategy can be effective to reduce lung injury from spontaneous effort while maintaining some muscle activity. The recent clinical trial to reevaluate systemic early neuromuscular blockade in moderate-severe ARDS (i.e., reevaluation of systemic early neuromuscular blockade (ROSE) trial) support that a higher PEEP strategy can facilitate 'safe' spontaneous breathing under the light sedation targets (i.e., no increase in barotrauma nor 90 days mortality versus early muscle paralysis).

SUMMARY

To prevent P-SILI in ARDS, it seems feasible to facilitate 'safe' spontaneous breathing in patients using a higher PEEP strategy in severe ARDS.

Spontaneous effort causes occult pendelluft during mechanical ventilation.

Yoshida T, Torsani V, Gomes S, et al. Spontaneous effort causes occult pendelluft during mechanical ventilation. Am J Respir Crit Care Med. 2013;188(12):1420‑1427. doi:10.1164/rccm.201303‑0539OC



RATIONALE

In normal lungs, local changes in pleural pressure (P(pl)) are generalized over the whole pleural surface. However, in a patient with injured lungs, we observed (using electrical impedance tomography) a pendelluft phenomenon (movement of air within the lung from nondependent to dependent regions without change in tidal volume) that was caused by spontaneous breathing during mechanical ventilation.

OBJECTIVES

To test the hypotheses that in injured lungs negative P(pl) generated by diaphragm contraction has localized effects (in dependent regions) that are not uniformly transmitted, and that such localized changes in P(pl) cause pendelluft.

METHODS

We used electrical impedance tomography and dynamic computed tomography (CT) to analyze regional inflation in anesthetized pigs with lung injury. Changes in local P(pl) were measured in nondependent versus dependent regions using intrabronchial balloon catheters. The airway pressure needed to achieve comparable dependent lung inflation during paralysis versus spontaneous breathing was estimated.

MEASUREMENTS AND MAIN RESULTS

In all animals, spontaneous breathing caused pendelluft during early inflation, which was associated with more negative local P(pl) in dependent regions versus nondependent regions (‑13.0 ± 4.0 vs. ‑6.4 ± 3.8 cm H2O; P < 0.05). Dynamic CT confirmed pendelluft, which occurred despite limitation of tidal volume to less than 6 ml/kg. Comparable inflation of dependent lung during paralysis required almost threefold greater driving pressure (and tidal volume) versus spontaneous breathing (28.0 ± 0.5 vs. 10.3 ± 0.6 cm H2O, P < 0.01; 14.8 ± 4.6 vs. 5.8 ± 1.6 ml/kg, P < 0.05).

CONCLUSIONS

Spontaneous breathing effort during mechanical ventilation causes unsuspected overstretch of dependent lung during early inflation (associated with reciprocal deflation of nondependent lung). Even when not increasing tidal volume, strong spontaneous effort may potentially enhance lung damage.

High Positive End‑Expiratory Pressure Renders Spontaneous Effort Noninjurious.

Morais CCA, Koyama Y, Yoshida T, et al. High Positive End‑Expiratory Pressure Renders Spontaneous Effort Noninjurious. Am J Respir Crit Care Med. 2018;197(10):1285‑1296. doi:10.1164/rccm.201706‑1244OC



RATIONALE

In acute respiratory distress syndrome (ARDS), atelectatic solid‑like lung tissue impairs transmission of negative swings in pleural pressure (Ppl) that result from diaphragmatic contraction. The localization of more negative Ppl proportionally increases dependent lung stretch by drawing gas either from other lung regions (e.g., nondependent lung [pendelluft]) or from the ventilator. Lowering the level of spontaneous effort and/or converting solid‑like to fluid‑like lung might render spontaneous effort noninjurious.

OBJECTIVES

To determine whether spontaneous effort increases dependent lung injury, and whether such injury would be reduced by recruiting atelectatic solid-like lung with positive end-expiratory pressure (PEEP).

METHODS

Established models of severe ARDS (rabbit, pig) were used. Regional histology (rabbit), inflammation (positron emission tomography; pig), regional inspiratory Ppl (intrabronchial balloon manometry), and stretch (electrical impedance tomography; pig) were measured. Respiratory drive was evaluated in 11 patients with ARDS.

MEASUREMENTS AND MAIN RESULTS

Although injury during muscle paralysis was predominantly in nondependent and middle lung regions at low (vs. high) PEEP, strong inspiratory effort increased injury (indicated by positron emission tomography and histology) in dependent lung. Stronger effort (vs. muscle paralysis) caused local overstretch and greater tidal recruitment in dependent lung, where more negative Ppl was localized and greater stretch was generated. In contrast, high PEEP minimized lung injury by more uniformly distributing negative Ppl, and lowering the magnitude of spontaneous effort (i.e., deflection in esophageal pressure observed in rabbits, pigs, and patients).

CONCLUSIONS

Strong effort increased dependent lung injury, where higher local lung stress and stretch was generated; effort-dependent lung injury was minimized by high PEEP in severe ARDS, which may offset need for paralysis.

Exacerbation of acute pulmonary edema during assisted mechanical ventilation using a low‑tidal volume, lung‑protective ventilator strategy.

Kallet RH, Alonso JA, Luce JM, Matthay MA. Exacerbation of acute pulmonary edema during assisted mechanical ventilation using a low‑tidal volume, lung‑protective ventilator strategy. Chest. 1999;116(6):1826‑1832. doi:10.1378/chest.116.6.1826



STUDY OBJECTIVES

To assess the magnitude of negative intrathoracic pressure development in a patient whose pulmonary edema acutely worsened immediately following the institution of a low‑tidal volume (VT) strategy.

DESIGN

Mechanical lung modeling of patient-ventilator interactions based on data from a case report.

SETTING

Medical ICU and laboratory.

PATIENT

A patient with suspected ARDS and frank pulmonary edema.

INTERVENTIONS

The patient's pulmonary mechanics and spontaneous breathing pattern were measured. Samples of arterial blood and pulmonary edema fluid were obtained.

MEASUREMENTS

A standard work-of-breathing lung model was used to mimic the ventilator settings, pulmonary mechanics, and spontaneous breathing pattern observed when pulmonary edema worsened. Comparison of the pulmonary edema fluid-to-plasma total protein concentration ratio was made.

RESULTS

The patient's spontaneous VT demand was greater than preset. The lung model revealed simulated intrathoracic pressure changes consistent with levels believed necessary to produce pulmonary edema during obstructed breathing. A high degree of imposed circuit-resistive work was found. The pulmonary edema fluid-to-plasma total protein concentration ratio was 0.47, which suggested a hydrostatic mechanism.

CONCLUSION

Ventilator adjustments that greatly increase negative intrathoracic pressure during the acute phase of ARDS may worsen pulmonary edema by increasing the transvascular pressure gradient. Therefore, whenever sedation cannot adequately suppress spontaneous breathing (and muscle relaxants are contraindicated), a low-VT strategy should be modified by using a pressure-regulated mode of ventilation, so that imposed circuit-resistive work does not contribute to the deterioration of the patient's hemodynamic and respiratory status.

Fluid Balance Is Associated with Clinical Outcomes and Extravascular Lung Water in Children with Acute Asthma Exacerbation.

Kantor DB, Hirshberg EL, McDonald MC, et al. Fluid Balance Is Associated with Clinical Outcomes and Extravascular Lung Water in Children with Acute Asthma Exacerbation. Am J Respir Crit Care Med. 2018;197(9):1128‑1135. doi:10.1164/rccm.201709‑1860OC



RATIONALE

The effects of fluid administration during acute asthma exacerbation are likely unique in this patient population: highly negative inspiratory intrapleural pressure resulting from increased airway resistance may interact with excess fluid administration to favor the accumulation of extravascular lung water, leading to worse clinical outcomes.

OBJECTIVES

Investigate how fluid balance influences clinical outcomes in children hospitalized for asthma exacerbation.

METHODS

We analyzed the association between fluid overload and clinical outcomes in a retrospective cohort of children admitted to an urban children's hospital with acute asthma exacerbation. These findings were validated in two cohorts: a matched retrospective and a prospective observational cohort. Finally, ultrasound imaging was used to identify extravascular lung water and investigate the physiological basis for the inferential findings.

MEASUREMENTS AND MAIN RESULTS

In the retrospective cohort, peak fluid overload [(fluid input ‑ output)/weight] is associated with longer hospital length of stay, longer treatment duration, and increased risk of supplemental oxygen use (P values < 0.001). Similar results were obtained in the validation cohorts. There was a strong interaction between fluid balance and intrapleural pressure: the combination of positive fluid balance and highly negative inspiratory intrapleural pressures is associated with signs of increased extravascular lung water (P < 0.001), longer length of stay (P = 0.01), longer treatment duration (P = 0.03), and increased risk of supplemental oxygen use (P = 0.02).

CONCLUSIONS

Excess volume administration leading to fluid overload in children with acute asthma exacerbation is associated with increased extravascular lung water and worse clinical outcomes.

Asynchronies during mechanical ventilation are associated with mortality.

Blanch L, Villagra A, Sales B, et al. Asynchronies during mechanical ventilation are associated with mortality. Intensive Care Med. 2015;41(4):633‑641. doi:10.1007/s00134‑015‑3692‑6



PURPOSE

This study aimed to assess the prevalence and time course of asynchronies during mechanical ventilation (MV).

METHODS

Prospective, noninterventional observational study of 50 patients admitted to intensive care unit (ICU) beds equipped with Better Care™ software throughout MV. The software distinguished ventilatory modes and detected ineffective inspiratory efforts during expiration (IEE), double‑triggering, aborted inspirations, and short and prolonged cycling to compute the asynchrony index (AI) for each hour. We analyzed 7,027 h of MV comprising 8,731,981 breaths.

RESULTS

Asynchronies were detected in all patients and in all ventilator modes. The median AI was 3.41 % [IQR 1.95-5.77]; the most common asynchrony overall and in each mode was IEE [2.38 % (IQR 1.36-3.61)]. Asynchronies were less frequent from 12 pm to 6 am [1.69 % (IQR 0.47-4.78)]. In the hours where more than 90 % of breaths were machine-triggered, the median AI decreased, but asynchronies were still present. When we compared patients with AI > 10 vs AI ≤ 10 %, we found similar reintubation and tracheostomy rates but higher ICU and hospital mortality and a trend toward longer duration of MV in patients with an AI above the cutoff.

CONCLUSIONS

Asynchronies are common throughout MV, occurring in all MV modes, and more frequently during the daytime. Further studies should determine whether asynchronies are a marker for or a cause of mortality.

Comparison of magnetic and electrical phrenic nerve stimulation in assessment of diaphragmatic contractility.

Laghi F, Harrison MJ, Tobin MJ. Comparison of magnetic and electrical phrenic nerve stimulation in assessment of diaphragmatic contractility. J Appl Physiol (1985). 1996;80(5):1731‑1742. doi:10.1152/jappl.1996.80.5.1731

Unlike the standard electrical approach, cervical magnetic stimulation of the phrenic nerves is less painful and achieves a constant degree of diaphragmatic recruitment, features that should enhance its applicability in a clinical setting. An unexplained phenomenon is the greater transdiaphragmatic twitch pressure (Pditw) with magnetic vs. electrical stimulation. We hypothesized that this greater Pditw is due to coactivation of extradiaphragmatic muscles. Because impedance to rib cage expansion is increased at high lung volumes and efficiency of extradiaphragmatic muscles is less than that of the diaphragm, we reasoned that the difference between electrical Pditw and magnetic Pditw would be less evident at high volumes than at end‑expiratory lung volume. In human volunteers, magnetic Pditw and electrical Pditw were 37.7 +/‑ 1.9 (SE) and 32.3 +/‑ 2.2 cmH2O, respectively, at end‑expiratory lung volume (P < 0.005) and 24.0 +/‑ 2.9 and 27.2 +/‑ 2.8 cmH2O, respectively, at one‑half inspiratory capacity (not significant); at total lung capacity, magnetic Pditw was less than electrical Pditw (10.6 +/‑ 0.8 and 16.2 +/‑ 2.9 cmH2O, respectively; P < 0.05). Magnetic stimulation caused significant extradiaphragmatic muscle depolarization and rib cage expansion, whereas electrical stimulation caused virtually no extradiaphragmatic muscle depolarization and rib cage deflation. Despite these differences, the induction of respiratory muscle fatigue produced reductions in both electrical and magnetic Pditw values (P < 0.01), which were of similar magnitude and closely correlated (r = 0.96). In conclusion, magnetic stimulation recruits both extradiaphragmatic and diaphragmatic muscles, and it is equally as effective as electrical stimulation in detecting diaphragmatic fatigue.

Effects of Positive End‑Expiratory Pressure and Spontaneous Breathing Activity on Regional Lung Inflammation in Experimental Acute Respiratory Distress Syndrome.

Kiss T, Bluth T, Braune A, et al. Effects of Positive End‑Expiratory Pressure and Spontaneous Breathing Activity on Regional Lung Inflammation in Experimental Acute Respiratory Distress Syndrome. Crit Care Med. 2019;47(4):e358‑e365. doi:10.1097/CCM.0000000000003649



OBJECTIVES

To determine the impact of positive end‑expiratory pressure during mechanical ventilation with and without spontaneous breathing activity on regional lung inflammation in experimental nonsevere acute respiratory distress syndrome.

DESIGN

Laboratory investigation.

SETTING

University hospital research facility.

SUBJECTS

Twenty-four pigs (28.1-58.2 kg).

INTERVENTIONS

In anesthetized animals, intrapleural pressure sensors were placed thoracoscopically in ventral, dorsal, and caudal regions of the left hemithorax. Lung injury was induced with saline lung lavage followed by injurious ventilation in supine position. During airway pressure release ventilation with low tidal volumes, positive end-expiratory pressure was set 4 cm H2O above the level to reach a positive transpulmonary pressure in caudal regions at end-expiration (best-positive end-expiratory pressure). Animals were randomly assigned to one of four groups (n = 6/group; 12 hr): 1) no spontaneous breathing activity and positive end-expiratory pressure = best-positive end-expiratory pressure - 4 cm H2O, 2) no spontaneous breathing activity and positive end-expiratory pressure = best-positive end-expiratory pressure + 4 cm H2O, 3) spontaneous breathing activity and positive end-expiratory pressure = best-positive end-expiratory pressure + 4 cm H2O, 4) spontaneous breathing activity and positive end-expiratory pressure = best-positive end-expiratory pressure - 4 cm H2O.

MEASUREMENTS AND MAIN RESULTS

Global lung inflammation assessed by specific [F]fluorodeoxyglucose uptake rate (median [25-75% percentiles], min) was decreased with higher compared with lower positive end-expiratory pressure both without spontaneous breathing activity (0.029 [0.027-0.030] vs 0.044 [0.041-0.065]; p = 0.004) and with spontaneous breathing activity (0.032 [0.028-0.043] vs 0.057 [0.042-0.075]; p = 0.016). Spontaneous breathing activity did not increase global lung inflammation. Lung inflammation in dorsal regions correlated with transpulmonary driving pressure from spontaneous breathing at lower (r = 0.850; p = 0.032) but not higher positive end-expiratory pressure (r = 0.018; p = 0.972). Higher positive end-expiratory pressure resulted in a more homogeneous distribution of aeration and regional transpulmonary pressures at end-expiration along the ventral-dorsal gradient, as well as a shift of the perfusion center toward dependent zones in the presence of spontaneous breathing activity.

CONCLUSIONS

In experimental mild-to-moderate acute respiratory distress syndrome, positive end-expiratory pressure levels that stabilize dependent lung regions reduce global lung inflammation during mechanical ventilation, independent from spontaneous breathing activity.

Early Neuromuscular Blockade in the Acute Respiratory Distress Syndrome.

National Heart, Lung, and Blood Institute PETAL Clinical Trials Network, Moss M, Huang DT, et al. Early Neuromuscular Blockade in the Acute Respiratory Distress Syndrome. N Engl J Med. 2019;380(21):1997‑2008. doi:10.1056/NEJMoa1901686



BACKGROUND

The benefits of early continuous neuromuscular blockade in patients with acute respiratory distress syndrome (ARDS) who are receiving mechanical ventilation remain unclear.

METHODS

We randomly assigned patients with moderate‑to‑severe ARDS (defined by a ratio of the partial pressure of arterial oxygen to the fraction of inspired oxygen of <150 mm Hg with a positive end‑expiratory pressure [PEEP] of ≥8 cm of water) to a 48‑hour continuous infusion of cisatracurium with concomitant deep sedation (intervention group) or to a usual‑care approach without routine neuromuscular blockade and with lighter sedation targets (control group). The same mechanical‑ventilation strategies were used in both groups, including a strategy involving a high PEEP. The primary end point was in‑hospital death from any cause at 90 days.

RESULTS

The trial was stopped at the second interim analysis for futility. We enrolled 1006 patients early after the onset of moderate-to-severe ARDS (median, 7.6 hours after onset). During the first 48 hours after randomization, 488 of the 501 patients (97.4%) in the intervention group started a continuous infusion of cisatracurium (median duration of infusion, 47.8 hours; median dose, 1807 mg), and 86 of the 505 patients (17.0%) in the control group received a neuromuscular blocking agent (median dose, 38 mg). At 90 days, 213 patients (42.5%) in the intervention group and 216 (42.8%) in the control group had died before hospital discharge (between-group difference, -0.3 percentage points; 95% confidence interval, -6.4 to 5.9; P = 0.93). While in the hospital, patients in the intervention group were less physically active and had more adverse cardiovascular events than patients in the control group. There were no consistent between-group differences in end points assessed at 3, 6, and 12 months.

CONCLUSIONS

Among patients with moderate-to-severe ARDS who were treated with a strategy involving a high PEEP, there was no significant difference in mortality at 90 days between patients who received an early and continuous cisatracurium infusion and those who were treated with a usual-care approach with lighter sedation targets. (Funded by the National Heart, Lung, and Blood Institute; ROSE ClinicalTrials.gov number, NCT02509078.).

The role of PEEP in patients with chronic obstructive pulmonary disease during assisted ventilation.

Rossi A, Brandolese R, Milic‑Emili J, Gottfried SB. The role of PEEP in patients with chronic obstructive pulmonary disease during assisted ventilation. Eur Respir J. 1990;3(7):818‑822.

In patients with acute respiratory failure (ARF) due to acute exacerbation of chronic obstructive pulmonary disease (COPD), the intrinsic positive end‑expiratory pressure (PEEPi) can significantly increase workload for ventilation. It has been suggested that, in the presence of expiratory flow limitation, application of low levels of PEEP by the ventilator can be used to reduce PEEPi and therefore the magnitude of the inspiratory effort during assisted mechanical ventilation (or pressure support) and weaning. Clearly, pulmonary hyperinflation should not be further enhanced in order not to counteract the beneficial effect of removing PEEPi by decreasing respiratory muscle length and force. This use of PEEP in COPD patients is supported not only by theory, but also by recent experimental work, although sufficient clinical information is not yet available to provide a guideline for titration of the PEEP level. Therefore, application of PEEP in COPD patients requires close monitoring of the end‑expiratory lung volume. This can be accomplished, among other noninvasive ways (e.g. the inductive plethysmography), by inspection of flow/volume curves during application of increasing levels of PEEP. The shape of the expiratory limb of the flow/volume curve can also suggest the presence of dynamic hyperinflation and expiratory flow limitation.