The effect of preemptive airway pressure release ventilation on patients with high risk for acute respiratory distress syndrome: a randomized controlled trial

Küçük, Mehtap Pehlivanlar; Erman Öztürk, Çağatay; Köylü İlkaya, Nazan; Küçük, Ahmet Oğuzhan; Ergül, Dursun Fırat; Ülger, Fatma

doi:10.1016/j.bjane.2021.03.022

Abstract

Background and objectives:

The objective of this study was to investigate the use of early APRV mode as a lung protective strategy compared to conventional methods with regard to ARDS development.

Methods:

The study was designed as a randomized, non-blinded, single-center, superiority trial with two parallel groups and a primary endpoint of ARDS development. Patients under invasive mechanical ventilation who were not diagnosed with ARDS and had Lung Injury Prediction Score greater than 7 were included in the study. The patients were assigned to APRV and P-SIMV + PS mode groups.

Results:

Patients were treated with P-SIMV+PS or APRV mode; 33 (50.8%) and 32 (49.2%), respectively. The P/F ratio values were higher in the APRV group on day 3 (p = 0.032). The fraction of inspired oxygen value was lower in the APRV group at day 7 (p = 0.011).While 5 of the 33 patients (15.2%) in the P-SIMV+PS group developed ARDS, one out of the 32 patients (3.1%) in the APRV group developed ARDS during follow-up (p = 0.197). The groups didn’t differ in terms of vasopressor/inotrope requirement, successful extubation rates, and/or mortality rates (p = 1.000, p = 0.911, p = 0.705, respectively). Duration of intensive care unit stay was 8 (2-11) days in the APRV group and 13 (8-81) days in the P-SIMV+PS group (p = 0.019).

Conclusions:

The APRV mode can be used safely in selected groups of surgical and medical patients while preserving spontaneous respiration to a make benefit of its lung-protective effects. In comparison to the conventional mode, it is associated with improved oxygenation, higher mean airway pressures, and shorter intensive care unit stay. However, it does not reduce the sedation requirement, ARDS development, or mortality.

KEYWORDS
Acute respiratory distress syndrome; APRV ventilation mode; Bi-level continuous positive airway pressure; intensive care unit; Ventilation modes

Introduction

Airway pressure release ventilation (APRV) is a mode of mechanical ventilation that alternates between two levels of continuous positive airway pressure (CPAP) support. Additionally, it allows spontaneous respiratory effort at either CPAP level.¹1 Garner W, Downs JB, Stock MC, et al. Airway pressure release ventilation (APRV). A human trial. Chest. 1988;94:779-81. It is considered as an alternative, life-saving modality in patients with acute respiratory distress syndrome (ARDS) that struggle for oxygenation.²2 Dries DJ, Marini JJ. Airway pressure release ventilation. J Burn Care Res. 2009;PAP:929-36. Compared to the classical ventilation, APRV has been shown to provide lower peak pressure, better oxygenation, less circulatory loss, and better gas exchange without deteriorating the hemodynamic condition of the ARDS patient.³3 Habashi N, Andrews P. Ventilator strategies for posttraumatic acute respiratory distress syndrome: airway pressure release ventilation and the role of spontaneous breathing in critically ill patients. Curr Opin Crit Care. 2004;10:549-57. This mode is believed to help to achieve the target of opening consolidated lung areas (recruitment) and to prevent repeated opening-closing of alveoli (decruitment). However, there is still insufficient and limited proof to support this hypothesis.

Recently, it has been proposed that the early use of protective mechanical ventilation with APRV could be used preemptively to prevent the development of ARDS in high risk patients.⁴4 Andrews PL, Shiber JR, Jaruga-Killeen E, et al. Early application of airway pressure release ventilation may reduce mortality in high-risk trauma patients: a systematic review of observational trauma ARDS literature. J Trauma Acute Care Surg. 2013;75:635-41.

5 Zhou Y, Jin X, Lv Y, et al. Early application of airway pressure release ventilation may reduce the duration of mechanical ventilation in acute respiratory distress syndrome. Intensive Care Med. 2017;43:1648-59.

6 Roy S, Habashi N, Sadowitz B, et al. Early airway pressure release ventilation prevents ARDS-a novel preventive approach to lung injury. Shock. 2013;39:28-38.

7 Sadowitz B. Preemptive mechanical ventilation can block progressive acute lung injury. World J Crit Care Med. 2016;5:74.-⁸8 Emr B, Gatto LA, Roy S, et al. Airway pressure release ventilation prevents ventilator-induced lung injury in normal lungs. JAMA Surg. 2013;148:1005-12. In that study, APRV prevented clinical and histological lung injury by protecting alveolar epithelial integrity, preserving surfactant and alveolar stability, and reducing pulmonary edema.⁶6 Roy S, Habashi N, Sadowitz B, et al. Early airway pressure release ventilation prevents ARDS-a novel preventive approach to lung injury. Shock. 2013;39:28-38.

The primary purpose of the present study was to investigate the early use of APRV as a lung-protecting strategy compared to the conventionally used methods in a patient population with high risk of ARDS.

Methods

The CONSORT guideline was used as a guide for this manuscript. Our study was carried out in Ondokuz Mayıs University in the 3rd level intensive care unit patients. This study was planned as a single-centered, prospective, and randomized-controlled study in a general intensive care unit with an 18-bed capacity. The majority of the general patient population is made up of trauma and postoperative patients. The local ethics committee reviewed and approved the study protocol (protocol number: 2016/175) prior to the start of the investigation. The study was also registered on the ClinicalTrials with protocol nº NCT04699513. Enrollment for the study was performed from May 2016 to October 2018. Written informed consent was obtained from a relative of each patient.

Study design and sample

The study included patients who required invasive mechanical ventilation but was not initially diagnosed with ARDS⁹9 Ranieri VM, Rubenfeld GD, Thompson BT, et al. Acute respiratory distress syndrome: The Berlin definition. JAMA. 2012;307:2526-33.; had a LIPS (Lung Injury Prediction Score) greater than 7¹⁰; and stayed in the Intensive Care Unit (ICU) for more than 24 hours. Patient demographic properties, sedation requirements, inotrope/vasopressor levels, ARDS development status, length of ICU and hospital stay, and mechanical ventilation related parameters were recorded. Exclusion criteria were pregnancy, intracranial hypertension (suspected or confirmed by measurement with external ventricular drainage catheter), severe chronic obstructive pulmonary disease or type II respiratory failure, confirmed bronchopleural fistula, documented barotrauma, history of pneumonectomy, and age below 18 or above 85 years. Consecutive eligible patients were enrolled by block randomization with a 1:1 allocation ratio and randomly assigned to the APRV or the Pressure controlled Synchronized Intermittent Mandatory Ventilation + Pressure Support (P- SIMV+PS) groups using opaque, sealed envelopes.

Ventilator settings

All mechanical ventilation settings were made by intensivists or trained residents on the night shifts. Prior to randomization, all patients were treated with VC-SIMV mode. Patients admitted during the day were ventilated in VC-SIMV mode until the main investigators evaluated the patient (1-2 hours). The patient was admitted in the evening-night shift were ventilated in VC-SIMV mode until the main investigators took over the shift in the morning (maximum 16 hours). Assignment to groups was performed following the calculation of the LIPS score. Microprocessorcontrolled mechanical ventilators (Galileo GOLD; Hamilton Medical AG, Bonaduz, Switzerland) and heated humidifiers were used as a standard for all patients. In both groups, mechanical ventilation targets were determined as maintaining plateau airway pressure (P_plateu) < 30 cmH₂O and PaO₂ between 60-100 mmHg or SO₂ > 88%. In both groups, arterial blood gas measurement was performed at least twice a day. Oxygenation and respiratory mechanics were evaluated by comparing the P-SIMV+PS and the APRV groups at baseline and on days 1, 2, 3, and 7. Patients were followed until transfer to CPAP/T-tube and extubation or a maximum of 28 days. During this period, follow-up was terminated once at extubation, exitus, and/or when discharge from ICU or ARDS occurred.

P-SIMV+PS group

The reason behind using P-SIMV+PS as a conventional mode was that it has a pressure-controlled mode similar to the APRV. Pressure level was adjusted in order to get a Vt of 6-8 ml.kg^-1.PBW^-1 (predicted body weight). Optimal Positive End-Expiratory Pressure (PEEP) between 5-10 cmH₂O was applied to all patients by titration according to the O₂ requirement.

The APRV group

Standard initial settings were T_high/T_low: 4/0.8 seconds, P_high: taking P_plateau value (if patient is paralyzed) or P_mean in the previous conventional method as reference, P_plateau < 30 cm H₂0 and target Vt 6-8 mL.kg^-1 PBW^-1. P_low was always set to 0 cm H₂O. T_low was adjusted according to the PCO₂ value in blood gas measurement by evaluating expiratory flow curve (gas flow wave form), and to get a release duration of 10-14/cycle^-1. T_low range was adjusted as 0.4-1.2 seconds.¹²12 Daoud EG, Farag HL, Chatburn RL. Airway pressure release ventilation: what do we know? Respir Care. 2011;57:282-92.,¹³13 Roy SK, Emr B, Sadowitz B, et al. Preemptive application of airway pressure release ventilation prevents development of acute respiratory distress syndrome in a rat traumatic hemorrhagic shock model. Shock. 2013;40:210-6. Weaning was performed according to the European Respiratory Society Weaning Task Force recommendations in both groups.¹⁴14 Boles J-M, Bion J, Connors A, et al. Weaning from mechanical ventilation. Eur Respir J. 2007;29:1033-56.

Medical and supportive treatments

Fluidic management, antibiotic strategy, glucose control, and enteral nutrition were also standardized between the two groups according to the ICU protocols. The sedation goal was a Richmond Agitation Sedation Scale score of-2 to 0.¹⁵15 Devlin JW, Skrobik Y, Gélinas C, et al. Clinical practice guidelines for the prevention and management of pain, agitation/sedation, delirium, immobility, and sleep disruption in adult patients in the ICU. Crit Care Med. 2018;46, e825-73. The sedation doses were not evaluated. None of the patients received neuromuscular blocker.

Statistical analysis

The primary outcome of developing ARDS in the light of P/F ratio⁸8 Emr B, Gatto LA, Roy S, et al. Airway pressure release ventilation prevents ventilator-induced lung injury in normal lungs. JAMA Surg. 2013;148:1005-12. (Clinically defined ALI/ARDS developed in the CMV group - mean [SE] PaO2/FIO2 [P/F] ratio, 242.96 [S.E. 24.82]) was prevented with APRV (P/F ratio, 478.00 [S.E.41.38]; p < 0.05 vs CMV). The power analysis using the Gpower computer program¹¹11 Faul F, Erdfelder E, Lang AG, et al. G*Power 3: a flexible statistical power analysis program for the social, behavioral, and biomedical sciences. Behav Res Methods. 2007;39:175-91. Psychonomic Society Inc. indicated that a total sample of 58 people would be needed to detect large effects (d: 0.888) with a 90% power using a t-test between means with 2-tailed alpha at 0.05.

All data were analyzed using IBM SPSS version 23 (Chicago, USA). The Shapiro Wilk test was used to determine whether the data were normally distributed. Comparisons of data that were not normally distributed were made with the Kruskal Wallis test and the Mann Whitney U test. Categorical data were analyzed with the Pearson chi-square test. The groups were compared with regard to laboratory parameters measured on days 1, 2, 3, and 7. Non-normally distributed data were presented as median (min-max), while normally distributed data were presented as the mean ± standard deviation. Categorical data were expressed as frequency and percentage. A p-value of less than 0.05 was considered significant.

Study endpoint

The primary endpoint of the study was to investigate whether early use of APRV as a lung-protecting strategy was superior to the conventional methods in a patient population with high risk of ARDS as determined by the calculation of the LIPS score. The secondary endpoint was to determine whether this mode provided any improvement in oxygenation, airway pressures, sedation requirements, mechanical ventilation time, and length of ICU/hospital stay.

Results

Comparison of demographic and baseline data between patient groups

Sixty-five patients meeting the eligibility criteria were enrolled (Fig. 1). Seven patients were excluded from the study due to being diagnosed with ARDS. During the followup, 6 patients developed ARDS; however, their data were included in the baseline evaluation since ARDS occurred after day 7. Thirty-three (50.8%) patients were treated with P-SIMV+PS and 32 (49.2%) patients were treated with APRV. Twelve (18.5%) of the study participants were female and 53 (81.5%) were male. The most common diagnosis among primary ICU admission was general trauma in 48 (73.8%) of the patients. Properties of patients did not differ significantly between the two study groups (Table 1).

Figure 1
Flow diagram.

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Table 1
Comparison of demographics.

The median age and body weight did not differ between the groups (p = 0.509 and p = 0.402, respectively). Baseline LIPS, APACHE II, and SOFA (Sequential Organ Failure Assessment) scores did not show a statistically significant difference between the groups (Table 2).

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Table 2
Comparison of baseline properties of P-SIMV+PS and APRV groups.

While 5 of the 33 patients (15.2%) in the P-SIMV+PS group developed ARDS, one of 32 patients (3.1%) in the APRV group developed ARDS during follow-up (p = 0.197).

The groups did not differ in terms of vasopressor/inotrope requirement, successful extubation rates, and mortality rates (p = 1.000, p = 0.911, and p = 0.705, respectively). The mechanical ventilation time was 9 (3-65) days in the P-SIMV+PS group and 7.5 (2-29) days in the APRV group (p = 0.171). The ICU stay length was significantly higher in the P-SIMV+PS group (p = 0.019). Hospital stay length did not differ between the groups (p = 0.242). The comparison of the end points is shown in Table 3.

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Table 3
Comparison of outcomes of patients according to groups.

Statistics of surviving patients

There was no statistically significant difference between the groups regarding mortality. After excluding 31 patients with mortality, 16 of the remaining 34 surviving patients (47%) were in the P-SIMV+PS group, and 18 (53%) were in the APRV group. There was no difference between the groups regarding mechanical ventilation time or hospital stay length (p = 0.211 and p = 0.297, respectively). The ICU stay length was significantly shorter in the APRV group (p = 0.027) (Table 4).

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Table 4
Comparison of outcomes after exclusion of deceased patients.

Comparison of blood gas and mechanical ventilation parameters

The worst of blood gas measurement results during follow-up throughout days 1, 2, 3, and 7 were recorded. Partial carbon dioxide pressure (PCO₂) was numerically higher in the APRV group, although there was no statistically significant difference between the groups. Partial oxygen pressure (PO₂) did not differ between the groups; however, the P/F ratio was higher in the APRV group on all four days (p = 0.032). FiO₂ ratios were lower in the APRV group on days 2, 3 and 7, and the difference on day 7 was statistically significant (p = 0.011) (Fig. 2).

Figure 2
Box-plots graphics of arterial blood gases on follow-up days. Footnotes: Each figure shows different arterial blood gas parameters in follow up for the first three days of the SIMV-P and APRV groups.

The P_mean on mechanical ventilator was significantly lower in the P-SIMV+PS group on all four days. P_peak was significantly lower in the P-SIMV+PS group on day 1 (p = 0.015), while no significant difference was present on the other days.

Discussion

Our results showed improved oxygenation, increased mean airway pressure, and reduced length of ICU stay with the use of APRV compared to the P-SIMV+PS method in patients with a high risk of ARDS development as determined by LIPS score. Nevertheless, there was no difference between the two groups regarding incidence rate of ARDS development, which was the primary outcome of the study. There are several studies in literature showing improved oxygenation with early use of APRV mode in patients with ARDS.⁴4 Andrews PL, Shiber JR, Jaruga-Killeen E, et al. Early application of airway pressure release ventilation may reduce mortality in high-risk trauma patients: a systematic review of observational trauma ARDS literature. J Trauma Acute Care Surg. 2013;75:635-41.

5 Zhou Y, Jin X, Lv Y, et al. Early application of airway pressure release ventilation may reduce the duration of mechanical ventilation in acute respiratory distress syndrome. Intensive Care Med. 2017;43:1648-59.

6 Roy S, Habashi N, Sadowitz B, et al. Early airway pressure release ventilation prevents ARDS-a novel preventive approach to lung injury. Shock. 2013;39:28-38.

7 Sadowitz B. Preemptive mechanical ventilation can block progressive acute lung injury. World J Crit Care Med. 2016;5:74.-⁸8 Emr B, Gatto LA, Roy S, et al. Airway pressure release ventilation prevents ventilator-induced lung injury in normal lungs. JAMA Surg. 2013;148:1005-12.

LIPS is a scoring system that recognizes patients with high risk of ARDS at the early period as soon as they are admitted to the ICU.¹⁶16 Gajic O, Dabbagh O, Park PK, et al. Early identification of patients at risk of acute lung injury: evaluation of lung injury prediction score in a multicenter cohort study. Am J Respir Crit Care Med. 2011;183:462-70. Bauman Z.M. et al showed that a LIPS score above 7 was significantly associated with the risk of ARDS development.¹⁰10 Bauman ZM, Gassner MY, Coughlin MA, et al. Lung injury prediction score is useful in predicting acute respiratory distress syndrome and mortality in surgical critical care patients. Crit Care Res Pract. 2015;2015:157408. This score was initially evaluated on surgical patients, and was validated for a wide range of patient types including trauma patients. While surgical patients and potentially trauma patients were of primary concern of this score, it was also validated in a group of patients under the risk of shock, sepsis, and/or multiple organ dysfunction.¹⁷17 Villar J, Sulemanji D, Kacmarek RM. The acute respiratory distress syndrome. Curr Opin Crit Care. 2014;20:3-9.,¹⁸18 Durham RM, Moran JJ, Mazuski JE, et al. Multiple organ failure in trauma patients. J Trauma. 2003;55:608-16. ARDS occurred in a total of 6 out of 65 patients in the entire study group; only one of them was in the APRV group. This result suggests that, despite being able to prognosticate patients with more serious disease, LIPS score was not quite successful in predicting ARDS. This finding may be due to our heterogeneous and limited patient population. While the number of patients developing ARDS was less in the APRV group (3.1%), the difference was statistically insignificant. There are several human and animal studies in literature that have compared APRV against the conventional modes.¹⁹19 Dart IVBW, Maxwell RA, Richart CM, et al. Preliminary experience with airway pressure release ventilation in a trauma/surgical intensive care unit. J Trauma. 2005;59:71-6.

20 Varpula T, Jousela I, Niemi R, et al. Combined effects of prone positioning and airway pressure release ventilation on gas exchange in patients with acute lung injury. Acta Anaesthesiol Scand. 2003;47:516-24.

21 Hirshberg EL, Lanspa MJ, Peterson J, et al. Randomized feasibility trial of a low tidal volume-airway pressure release ventilation protocol compared with traditional airway pressure release ventilation and volume control ventilation protocols. Crit Care Med. 2018;46:1943-52.-²²22 Maxwell RA, Green JM, Waldrop J, et al. A randomized prospective trial of airway pressure release ventilation and low tidal volume ventilation in adult trauma patients with acute respiratory failure. J Trauma. 2010;69:501-10. Most of these studies are observational studies with a limited number of patients. While these have found improved oxygenation with the application of APRV mode, mortality has been evaluated in only a few studies; no difference has been found regarding mortality in comparison to other modes³3 Habashi N, Andrews P. Ventilator strategies for posttraumatic acute respiratory distress syndrome: airway pressure release ventilation and the role of spontaneous breathing in critically ill patients. Curr Opin Crit Care. 2004;10:549-57.,⁸8 Emr B, Gatto LA, Roy S, et al. Airway pressure release ventilation prevents ventilator-induced lung injury in normal lungs. JAMA Surg. 2013;148:1005-12. On the other hand, Carsetti et al detected reduction in hospital mortality as well in a recent study including acute hypoxemic patients.²³23 Carsetti A, Damiani E, Domizi R, et al. Airway pressure release ventilation during acute hypoxemic respiratory failure: a systematic review and meta-analysis of randomized controlled trials. Ann Intensive Care. 2019;9:44.

We found significantly improved oxygenation in the APRV group. The PaO₂/FiO₂ ratios, in particular, were numerically higher on all four days of follow-up in the APRV group. This difference became significant on day 3. The FiO₂ ratio was lower on all days in the APRV group, and the difference was significant on day 7. Recently, Zhou et al published a study underscoring the superiorities of APRV mode.¹⁵15 Devlin JW, Skrobik Y, Gélinas C, et al. Clinical practice guidelines for the prevention and management of pain, agitation/sedation, delirium, immobility, and sleep disruption in adult patients in the ICU. Crit Care Med. 2018;46, e825-73. In that single-centered study, the authors showed improved oxygenation and respiratory system compliance, decreased P_plateau as well as reduced durations of both mechanical ventilation and ICU stay in the APRV group. However, similar to our results, they did not find a difference in terms of mortality or hospital stay. A major limitation of that study by Zhou et al was reported as a lack of homogeneity between the groups with a greater number of comorbid conditions in the control group. Compared to our results, Zhou and colleagues results are quite different and the reason for these differences needs to be further investigated. Similar to our results, however, Maxvel et al did not find a reduced sedation requirement.²²22 Maxwell RA, Green JM, Waldrop J, et al. A randomized prospective trial of airway pressure release ventilation and low tidal volume ventilation in adult trauma patients with acute respiratory failure. J Trauma. 2010;69:501-10.

In contrast to many other studies, they found an increase in ventilator days, ICU length of stay, and ventilatorassociated pneumonia. They attributed these results to high baseline APACHE II (Acute Physiology and Chronic Health Evaluation II) scores of the patients.²²22 Maxwell RA, Green JM, Waldrop J, et al. A randomized prospective trial of airway pressure release ventilation and low tidal volume ventilation in adult trauma patients with acute respiratory failure. J Trauma. 2010;69:501-10. These contradicting results can certainly be explained by the difference in patient populations. A distinction of our study, on the other hand, is that we documented favorable results when APRV mode is applied as a preemptive treatment to non-ARDS patients with healthy lung tissue.

One of these favorable effects was that mean airway pressure on mechanical ventilator was higher in APRV group on all four days of follow-up. Due to the inverse I/E ratio, APRV results in higher P_mean than conventional lungprotective ventilation. In APRV, T_high is way longer than T_low; and therefore, it yields a higher P_mean for the same P_peak compared to the conventional ventilation. Time spent at high pressure in APRV generally corresponds to 80-90% of the respiratory cycle. A higher P_mean is directly proportional to PaO₂ due to alveolar recruitment. For all these reasons, high P_mean has been shown to be beneficial in ARDS patients (due to surfactant deactivation, atelectasis, and alveolar edema).²⁴24 Marini JJ, Ravenscraft SA. Mean airway pressure. Crit Care Med. 1992;20:1604.,²⁵25 Rasanen J, Cane RD, Downs JB, et al. Airway pressure release ventilation during acute lung injury: a prospective multicenter trial. Crit Care Med. 1991;19:1234-41. J-Q Li et al also compared the SIMV and APRV groups and found higher P_mean values in the APRV group, which is similar to our results.²⁶26 Li JQ, Li N, Han GJ, et al. Clinical research about airway pressure release ventilation for moderate to severe acute respiratory distress syndrome. Eur Rev Med Pharmacol Sci. 2016;20:2634-41. Contrary to our work, they included moderate and severe ARDS patients in the APRV group and found P_mean on day one as 21.2 ± 5.3 cm H₂O. In our study, P_mean was lower [16 (15-18.75) cmH₂O] compared to what was reported by J-Q Li et al (2016), although we found this value to be higher in the APRV group than in the conventional mode. This result shows that APRV mode can be used as a lung-protective method with increased patient comfort even with lower pressures in patients with spontaneous breathing who do not have ARDS. The fact that we did not observe complications, such as pneumothorax or arrhythmia, in our study patients may also be attributed to this lower airway pressures. Another interesting point is that patients did not develop hypercapnia even with low pressures and long T_high times. This can be explained by preservation of spontaneous respiration, improved V/Q ratio, and opening of microatelectasis (if present).³3 Habashi N, Andrews P. Ventilator strategies for posttraumatic acute respiratory distress syndrome: airway pressure release ventilation and the role of spontaneous breathing in critically ill patients. Curr Opin Crit Care. 2004;10:549-57.

In our study, the length of ICU stay was significantly shorter in the APRV group. The mechanical ventilation time was also shorter in the APRV group with a median of 7.5 days; however, the difference was statistically not significant. Similarly, there have been other studies reporting shorter ICU stay with APRV application.⁵5 Zhou Y, Jin X, Lv Y, et al. Early application of airway pressure release ventilation may reduce the duration of mechanical ventilation in acute respiratory distress syndrome. Intensive Care Med. 2017;43:1648-59.,²⁷27 Putensen C, Zech S, Wrigge H, et al. Long-Term Effects of spontaneous breathing during ventilatory support in patients with acute lung injury. Am J Respir Crit Care Med. 2001;164:43-9. Possible reasons for this may be improvements in pulmonary functions such as gas exchange and respiratory compliance and a reduced need for sedation and paralysis with early use of APRV mode.²⁷27 Putensen C, Zech S, Wrigge H, et al. Long-Term Effects of spontaneous breathing during ventilatory support in patients with acute lung injury. Am J Respir Crit Care Med. 2001;164:43-9.

28 Blanch L, Villagra A, Sales B, et al. Asynchronies during mechanical ventilation are associated with mortality. Intensive Care Med. 2015;41:633-41.-²⁹29 Habashi NM. Other approaches to open-lung ventilation: airway pressure release ventilation. Crit Care Med. 2005;33:S228-40. We did not find significant reduction in total sedation requirement; however, we did not evaluate the administered cumulative dose.

There are several limitations to this study. We did not evaluate patient ventilator asynchrony or the effect of the ability to respire spontaneously on patient compliance. Additionally, we did not evaluate the effects of APRV and conventional modes on patient mechanics. Another limitation was the limited number of patients due to an abundance of exclusion criteria. In addition, the surgical patient population was higher, which was thought to result in detection of less ARDS development than predicted with the LIPS score. For that reason, the ARDS-protective effect of APRV, which was the primary outcome, could not be evaluated effectively. Lastly, we did not evaluate total sedation dose although we examined whether patients had sedation requirement.

In conclusion, APRV can safely be used preemptively in selected groups of surgical and medical patients with preserved spontaneous breath in order to make benefit of its lung-protective effects. However, it does not reduce ARDS development or mortality. In comparison to the conventional mode, it is associated with improved oxygenation, higher mean airway pressures, and shorter ICU stay length. This study is one of the few studies including the patients with a high risk of ARDS that do not require high PEEP levels; nevertheless, it should be confirmed with larger scale studies.

Acknowledgments

We would like to acknowledge the www. makaletercume.com for their outstanding scientific proofreading and editing services provided for this manuscript. The authors have no commercial associations or fundings.

References

¹
Garner W, Downs JB, Stock MC, et al. Airway pressure release ventilation (APRV). A human trial. Chest. 1988;94:779-81.
²
Dries DJ, Marini JJ. Airway pressure release ventilation. J Burn Care Res. 2009;PAP:929-36.
³
Habashi N, Andrews P. Ventilator strategies for posttraumatic acute respiratory distress syndrome: airway pressure release ventilation and the role of spontaneous breathing in critically ill patients. Curr Opin Crit Care. 2004;10:549-57.
⁴
Andrews PL, Shiber JR, Jaruga-Killeen E, et al. Early application of airway pressure release ventilation may reduce mortality in high-risk trauma patients: a systematic review of observational trauma ARDS literature. J Trauma Acute Care Surg. 2013;75:635-41.
⁵
Zhou Y, Jin X, Lv Y, et al. Early application of airway pressure release ventilation may reduce the duration of mechanical ventilation in acute respiratory distress syndrome. Intensive Care Med. 2017;43:1648-59.
⁶
Roy S, Habashi N, Sadowitz B, et al. Early airway pressure release ventilation prevents ARDS-a novel preventive approach to lung injury. Shock. 2013;39:28-38.
⁷
Sadowitz B. Preemptive mechanical ventilation can block progressive acute lung injury. World J Crit Care Med. 2016;5:74.
⁸
Emr B, Gatto LA, Roy S, et al. Airway pressure release ventilation prevents ventilator-induced lung injury in normal lungs. JAMA Surg. 2013;148:1005-12.
⁹
Ranieri VM, Rubenfeld GD, Thompson BT, et al. Acute respiratory distress syndrome: The Berlin definition. JAMA. 2012;307:2526-33.
¹⁰
Bauman ZM, Gassner MY, Coughlin MA, et al. Lung injury prediction score is useful in predicting acute respiratory distress syndrome and mortality in surgical critical care patients. Crit Care Res Pract. 2015;2015:157408.
¹¹
Faul F, Erdfelder E, Lang AG, et al. G*Power 3: a flexible statistical power analysis program for the social, behavioral, and biomedical sciences. Behav Res Methods. 2007;39:175-91. Psychonomic Society Inc.
¹²
Daoud EG, Farag HL, Chatburn RL. Airway pressure release ventilation: what do we know? Respir Care. 2011;57:282-92.
¹³
Roy SK, Emr B, Sadowitz B, et al. Preemptive application of airway pressure release ventilation prevents development of acute respiratory distress syndrome in a rat traumatic hemorrhagic shock model. Shock. 2013;40:210-6.
¹⁴
Boles J-M, Bion J, Connors A, et al. Weaning from mechanical ventilation. Eur Respir J. 2007;29:1033-56.
¹⁵
Devlin JW, Skrobik Y, Gélinas C, et al. Clinical practice guidelines for the prevention and management of pain, agitation/sedation, delirium, immobility, and sleep disruption in adult patients in the ICU. Crit Care Med. 2018;46, e825-73.
¹⁶
Gajic O, Dabbagh O, Park PK, et al. Early identification of patients at risk of acute lung injury: evaluation of lung injury prediction score in a multicenter cohort study. Am J Respir Crit Care Med. 2011;183:462-70.
¹⁷
Villar J, Sulemanji D, Kacmarek RM. The acute respiratory distress syndrome. Curr Opin Crit Care. 2014;20:3-9.
¹⁸
Durham RM, Moran JJ, Mazuski JE, et al. Multiple organ failure in trauma patients. J Trauma. 2003;55:608-16.
¹⁹
Dart IVBW, Maxwell RA, Richart CM, et al. Preliminary experience with airway pressure release ventilation in a trauma/surgical intensive care unit. J Trauma. 2005;59:71-6.
²⁰
Varpula T, Jousela I, Niemi R, et al. Combined effects of prone positioning and airway pressure release ventilation on gas exchange in patients with acute lung injury. Acta Anaesthesiol Scand. 2003;47:516-24.
²¹
Hirshberg EL, Lanspa MJ, Peterson J, et al. Randomized feasibility trial of a low tidal volume-airway pressure release ventilation protocol compared with traditional airway pressure release ventilation and volume control ventilation protocols. Crit Care Med. 2018;46:1943-52.
²²
Maxwell RA, Green JM, Waldrop J, et al. A randomized prospective trial of airway pressure release ventilation and low tidal volume ventilation in adult trauma patients with acute respiratory failure. J Trauma. 2010;69:501-10.
²³
Carsetti A, Damiani E, Domizi R, et al. Airway pressure release ventilation during acute hypoxemic respiratory failure: a systematic review and meta-analysis of randomized controlled trials. Ann Intensive Care. 2019;9:44.
²⁴
Marini JJ, Ravenscraft SA. Mean airway pressure. Crit Care Med. 1992;20:1604.
²⁵
Rasanen J, Cane RD, Downs JB, et al. Airway pressure release ventilation during acute lung injury: a prospective multicenter trial. Crit Care Med. 1991;19:1234-41.
²⁶
Li JQ, Li N, Han GJ, et al. Clinical research about airway pressure release ventilation for moderate to severe acute respiratory distress syndrome. Eur Rev Med Pharmacol Sci. 2016;20:2634-41.
²⁷
Putensen C, Zech S, Wrigge H, et al. Long-Term Effects of spontaneous breathing during ventilatory support in patients with acute lung injury. Am J Respir Crit Care Med. 2001;164:43-9.
²⁸
Blanch L, Villagra A, Sales B, et al. Asynchronies during mechanical ventilation are associated with mortality. Intensive Care Med. 2015;41:633-41.
²⁹
Habashi NM. Other approaches to open-lung ventilation: airway pressure release ventilation. Crit Care Med. 2005;33:S228-40.

Publication Dates

Publication in this collection
28 Feb 2022
Date of issue
Jan-Feb 2022

History

Received
08 Mar 2020
Accepted
19 Mar 2021
Published
24 Apr 2021

This is an Open Access article distributed under the terms of the Creative Commons Attribution Non-Commercial No Derivative License, which permits unrestricted non-commercial use, distribution, and reproduction in any medium provided the original work is properly cited and the work is not changed in any way.

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Parameter		P-SIMV+PS	APRV	p
Demographic Sex^a a Pearson chi-square test, p < 0.05.	Female	4 (33.33)	8 (66.67)
	Male	29 (54.72)	24 (45.28)	0.309
BMI^a a Pearson chi-square test, p < 0.05.	< 30	29 (54.72)	24 (45.28)
	> 30	4 (33.33)	8 (66.67)	0.309
Diagnosis Surgical/Trauma ^a a Pearson chi-square test, p < 0.05.
	Intracranial	13 (61.9)	8 (38.1)
	Intra-abdominal	2 (66.67)	1 (33.33)
	Orthopedic	1 (20)	4 (80)
	Thoracic	6 (50)	6 (50)
	Spinal Cord	0 (0)	2 (100)
Surgical/Non-trauma ^a a Pearson chi-square test, p < 0.05.	Other	3 (60)	2 (40)
	Intra-abdominal	5 (62.5)	3 (37.5)
Medical ^a a Pearson chi-square test, p < 0.05.	Other	1 (100)	0 (0)
	Pulmonary	1 (25)	3 (75)
	Intra-abdominal	0 (0)	1 (100)
	Other	1 (33.33)	2 (66.67)	0.500
Sepsis^a a Pearson chi-square test, p < 0.05.	No	31 (54.39)	26 (45.61)
	Yes	2 (25)	6 (75)	0.149
Comorbidity Comorbidity^a a Pearson chi-square test, p < 0.05.	No	19 (47.5)	21 (52.5)
	Yes	14 (56.0)	11 (44.0)	0.680

	P-SIMV+PS	APRV	p
Age (year)^a a Mann Whitney U test, p < 0.05.	54 (18-81)	50 (18-74)	0.590
Weight (kg)^a a Mann Whitney U test, p < 0.05.	82 (60-110)	80 (23-120)	0.402
LIPS^a a Mann Whitney U test, p < 0.05.	9 (7-13)	8.5 (7-12)	0.226
APACHE II^a a Mann Whitney U test, p < 0.05.	17 (7-36)	17 (7-35)	0.509
SOFA^a a Mann Whitney U test, p < 0.05.	6 (3-19)	7 (3-18)	0.464

Parameter	P-SIMV+PS	APRV	p
Sedation	30 (91.0)	23 (71.9)	0.061
Vasopressor/Inotrope^a a Pearson chi-square test, p < 0.05.	23 (69.7)	23 (71.9)	1.000
ARDS^a a Pearson chi-square test, p < 0.05.	5 (15.2)	1 (3.1)	0.197
Tracheotomy^a a Pearson chi-square test, p < 0.05.	5 (15.2)	2 (6.3)	0.427
Extubation^a a Pearson chi-square test, p < 0.05.	19 (57.6)	17 (53.1)	0.911
Mortality^a a Pearson chi-square test, p < 0.05.	17 (51.5)	14 (43.8)	0.705

	P-SIMV+PS	APRV	p
Weight (kg)^a a Mann Whitney U test, p < 0.05.	83.5 (60-95)	82.5 (34-120)	0.646
LIPS^a a Mann Whitney U test, p < 0.05.	9 (7-11)	8.5 (7-12)	0.443
APACHE II^a a Mann Whitney U test, p < 0.05.	16 (7-24)	17 (7-35)	0.164
SOFA^a a Mann Whitney U test, p < 0.05.	4.5 (3-10)	6.5 (3-17)	0.050
Sedation (total/day)^a a Mann Whitney U test, p < 0.05.	6.5 (2-65)	3 (1-18)	0.170
Vasopressor/Inotrope (total/day)^a a Mann Whitney U test, p < 0.05.	2 (1-15)	6.5 (1-14)	0.093
MV/Extubation duration (total/day)^a a Mann Whitney U test, p < 0.05.	10 (3-65)	8 (2-26)	0.211
ICU stay (day)^a a Mann Whitney U test, p < 0.05.	23.5 (10-81)	11 (2-58)	0.027
Hospital stay (day)^a a Mann Whitney U test, p < 0.05.	33 (17-85)	25.5 (8-79)	0.297

Brasil

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Abstract

Background and objectives:

Methods:

Results:

Conclusions:

Introduction

Methods

Study design and sample

Ventilator settings

P-SIMV+PS group

The APRV group

Medical and supportive treatments

Statistical analysis

Study endpoint

Results

Comparison of demographic and baseline data between patient groups

Statistics of surviving patients

Comparison of blood gas and mechanical ventilation parameters

Discussion

Acknowledgments

References

Publication Dates

History