key: cord-0022162-mg0xuf99 authors: Wang, Qing-Yuan; Ji, Yu-Wei; An, Li-Xin; Cao, Lei; Xue, Fu-Shan title: Effects of individualized PEEP obtained by two different titration methods on postoperative atelectasis in obese patients: study protocol for a randomized controlled trial date: 2021-10-15 journal: Trials DOI: 10.1186/s13063-021-05671-1 sha: 32ad4046b632832a0142a3df9d071fb7ad81a455 doc_id: 22162 cord_uid: mg0xuf99 BACKGROUND: The incidence of postoperative pulmonary complications (PPCs) is higher in obese patients undergoing general anesthesia and mechanical ventilation due to the reduction of oxygen reserve, functional residual capacity, and lung compliance. Individualized positive end-expiratory pressure (iPEEP) along with other lung-protective strategies is effective in alleviating postoperative atelectasis. Here, we compared the best static lung compliance (Cstat) titration of iPEEP with electrical impedance tomography (EIT) titration to observe their effects on postoperative atelectasis in obese patients undergoing laparoscopic surgery. METHODS: A total number of 140 obese patients with BMI ≥ 32.5kg/m(2) undergoing elective laparoscopic gastric volume reduction and at moderate to high risk of developing PPCs will be enrolled and randomized into the optimal static lung compliance-directed iPEEP group and EIT titration iPEEP group. The primary endpoint will be pulmonary atelectasis measured and calculated by EIT immediately after extubation and 2 h after surgery. Secondary endpoints will be intraoperative oxygenation index, organ dysfunction, incidence of PPCs, hospital expenses, and length of hospital stay. DISCUSSION: Many iPEEP titration methods effective for normal weight patients may not be appropriate for obese patients. Although EIT-guided iPEEP titration is effective in obese patients, its high price and complexity limit its application in many clinical facilities. This trial will test the efficacy of iPEEP via the optimal static lung compliance-guided titration procedure by comparing it with EIT-guided PEEP titration. The results of this trial will provide a feasible and convenient method for anesthesiologists to set individualized PEEP for obese patients during laparoscopic surgery. TRIAL REGISTRATION: ClinicalTrials.govChiCTR2000039144. Registered on October 19, 2020 SUPPLEMENTARY INFORMATION: The online version contains supplementary material available at 10.1186/s13063-021-05671-1. The incidence of postoperative pulmonary complications (PPCs) in obese patients is as high as 18%, which is almost twice that in normal weight or overweight patients [1, 2] . It is widely acknowledged that PPCs cause a significant increase in morbidity and mortality, prolonged length of hospital stay and ICU stay, and increased treatment expenses [2, 3] . Considering that roughly 310 million patients undergo surgery worldwide annually [4] , reducing the rate of PPCs should have a positive impact on mortality and morbidity. It could also improve patients' prognosis and reduce health system expenses. According to an international expert consensus [5] , lung-protective ventilation strategies including low tidal volume [6] , recruitment maneuvers, individualized PEEP, and the lowest possible oxygen concentration have been associated with reduced incidence of postoperative pulmonary complications. Among these, individualized PEEP plays an important role in preventing processive alveolar collapse; however, no agreement has been reached about how to select individualized PEEP. Patients whose BMI equal to or exceed 35 kg/m 2 are more susceptible to developing PPCs compared with mild obese and normal weight patients. In obese patients, respiratory function is undermined due to the decreased oxygen reserve, respiratory compliance, and functional residual capacity [7] . Moreover, obese patients are prone to develop atelectasis, which is further exacerbated by general anesthesia and mechanical ventilation. When obese patients undergo laparoscopic surgery, the cephalic shift of diaphragm and elevated pleural pressure imposed by pneumoperitoneum increase the proportion of atelectatic lung tissue. An intraoperative higher level of PEEP with alveolar recruitment maneuvers may improve respiratory function in obese patients [7, 8] . Recently, PROBESE trial, an international randomized trial, using a higher level of PEEP (12 cmH 2 O) and ARM compared with a lower level of PEEP (4 cmH 2 O) in obese patients, did not reduce PPCs [1, 9] . The conclusion of this study was not consistent with previous studies [7, 8] . However, the lack of individual titration of PEEP is their major limitation [1] . Nestler and his colleagues [8] revealed that in obese patients undergoing elective laparoscopic surgery, compared to patients ventilated with a fixed PEEP of 5 cmH 2 O, patients ventilated with individualized PEEP titrated through an electrical impedance tomography (EIT)-guided procedure experience alleviated atelectasis, improved regional ventilation distribution and oxygenation, and decreased driving pressure. Therefore, for obese patients, the appropriate individual PEEP rather than a single high level of PEEP may be more beneficial. However, the EIT instrument is expensive, making it unavailable for many medical institutions. In some thoracic and abdominal operations, the scope of disinfection also limits its application. The complex techniques related to EIT further impair its feasibility in routine clinical practice. Therefore, some simple and highly feasible methods to titrate individualized PEEP for obese patients need to be found out. This trial is going to verify the hypothesis: individualized PEEP titrated by optimal static lung compliance (Cstat) in combination with other lung-protective ventilation strategies is not inferior to individualized PEEP titrated via EIT in terms of reducing atelectasis, improving oxygenation and reducing the incidence of PPCs in obese patients at moderate to high risk of developing PPCs. This parallel, two-arm, single-center, prospective, single-blind (investigator-initiated, assessor-blinded), randomized, controlled trial tests the hypothesis that individualized PEEP titration guided by optimal Cstat is a convenient and feasible lung-protective strategy for obese patients at moderate to high risk for PPCs undergoing laparoscopic surgery. 140 patients will be randomly divided into one of two different groups (see Consolidated Standards of Reporting Trials [CONSORT] diagram, Fig. 1 Blinding, data collection, randomization, and recordkeeping This is a single-blind randomized clinical trial. Demographic parameters, intraoperative data, postoperative clinical status, fluid balance, hemodynamic variables, respiratory parameters, anesthesia data, laboratory results, and hygienic indicators will be recorded onto the case report forms (CRF). The information of lung collapse calculated by EIT will be stored in the computer and named with an anonymous number. All participants meeting the inclusion criteria will be randomized to the Cstat-PEEP group or the EIT-PEEP group in a ratio of 1:1. Randomization will be implemented via a computer-generated blocked randomization form, with 35 blocks of four patients per block. The assignment will proceed with opaque, sealed, and numbered envelopes. Subjects shall be enrolled and allocated in numerical order. All original records (CRF and associated correspondence) will be archived and safeguarded for 10 years and then destroyed, as required by hospital standards. Obese patients scheduled for laparoscopic gastric volume reduction surgery under general anesthesia will be screened and recruited during routine preoperative evaluation. Patients are eligible if they meet the following inclusion criteria: 18-60 years old, BMI≥32.5, at the American Society of Anesthesiologists (ASA) Physical Statuses I-III, and at moderate to high risk of developing postoperative pulmonary complications (PPCs). To identify patients at moderate to severe risk for PPCs, the Assess Respiratory Risk in Surgical Patients in Catalonia (ARISCAT) score [9] is applied (see Additional Fig 1) . This score predicts individual preoperative risk for developing PPCs with seven predictors, four of which are patient-associated, the other three are surgeryassociated. An ARISCAT score ≥26 is related to a moderate to severe risk for PPCs. We use BMI ≥ 32.5 as the standard for morbid obesity under the Asia-Pacific classification [10] . Exclusion criteria are patients aged>60 years or <18 years, ASA grade ≥ IV, with severe chronic obstructive pulmonary disease (COPD, defined as GOLD grades III-IV), having a history of severe or uncontrollable asthma, a history of pulmonary metastasis, in preoperative ongoing renal replacement therapy, with congestive heart failure (defined as NYHA grades III-IV), and failure to be extubated in time after surgery and the need for transference to the ICU with the endotracheal tube. To avoid interfering the trial intervention, components of perioperative anesthesia care (involving general anesthesia, postoperative analgesia, and fluid management) are performed by a fairly fixed team of anesthesiologists in accordance with the clinical routine. The following strategies are recommended: 1. Before surgery, all patients need a thorough assessment of the airway, performed on the basis of 12 predictors of a difficult airway. When more than three of the predictors are present, endotracheal intubation is performed when patients are awake or after slow induction while maintaining spontaneous breathing should be taken into consideration. Adequate equipment, personnel, and medicine required for artificial airway establishment should be prepared in advance (see Additional Table 1 : Predictors of Difficult Airway). 2. According to clinical routine, upon admission to the operation room, patients' following parameters are monitored: electrocardiogram, non-invasive blood pressure, BIS, pulse oximetry, and urine output. Invasive arterial blood pressure is continuously measured after the insertion of an arterial line into the radial or dorsal pedis artery under regional anesthesia. 3. After intravenous and arterial catheterization, an EIT belt will be placed at the fifth intercostal space, and continuous EIT monitoring (PulmoVista 500, Drager) will be started. 4. For patients without predicted difficult airway, anesthesia induction is performed using rapid sequence induction: 0.05mg/kg midazolam is given to patients 15 min before induction; sufentanil, etomidate, rocuronium, or cisatracurium are used for induction. Mechanical ventilation is initiated after endotracheal intubation. 5. Total intravenous anesthesia is applied for the maintenance of anesthesia with propofol and remifentanil. 6. Intraoperative hemodynamics is managed in accordance with surgical procedure and blood loss. 7. Performing postoperative analgesia to ensure a VAS pain score<3. Regional anesthesia or neuraxial block should be applied whenever indicated. 8. Postoperative physiotherapy involving early mobilization and stimulation of cough along with deep breathing exercises should be performed. Data related to the procedures applied shall be collected in detail and analyzed. Anesthesia care and associated treatment must abide by clinical routines. Intravenous catheters and nasogastric tubes may be used in accordance with guidelines or surgical practice. Urinary bladder catheters are usually not applied routinely for this sort of surgery in our hospital. The following are ventilator settings: We set the driving pressure to 15cmH 2 O, using pressure-control-volume compensation mode (PSV-VC). The lowest possible fraction of inspired oxygen is used (FiO 2 ≥0.4) to avoid hypoxemia (defined as SpO 2 >92%). The compensated tidal volume is fixed at 7ml/kg (PBW), and the respiratory rate is set to 12-15 times/minute (adjusted to normocapnia, defined as P ET CO 2 maintained at 35-45 cmH 2 O). Management of anesthesia maintenance is left to the discretion of the anesthesiologist in charge. All complications related to anesthesia are managed in accordance with clinical guidelines. After endotracheal intubation, and initiation of mechanical ventilation PEEP is maintained at 5cmH 2 O for 5 minutes, baseline parameters are measured and recorded in all patients during this period. All patients (in both groups) are submitted to ventilator-driven alveolar recruitment maneuvers (RM) 5 min after endotracheal intubation [11] , and then, the same procedure is repeated after finishing PEEP titration and before extubation (Fig. 2) . RM is performed in the following steps ( Fig. 3 After the first RM is performed, the individualized PEEP will be titrated by optimal Cstat or EIT according to their grouping information. According to a study conducted by Pereira SM et al. [12] , patients in the EIT-PEEP group will be performed an EIT-guided decremental PEEP titration procedure as following (Fig. 4 ): 1. After the first RM is performed, immediately after the establishment of pneumoperitoneum, PEEP titration is started. PEEP is started at 20 cmH 2 O and inspiratory pressure at 40 cmH 2 O. PEEP will be decreased at steps of 2 cmH 2 O every 40s, and respiratory rate maintained at 20 breaths/min, inspiratory pause at 30%, and V T = 6 ml/kg. 2. After the procedure comes to an end, a graph is automatically plotted and displayed by the EIT monitor, which shows the percentage of collapsed and overdistended lung units (equivalent to the percent mass of overdistended or collapsed lung tissue) at each PEEP level. 3. PEEP-EIT is determined as the nearest PEEP above the intersection of the curves representing collapse or overdistension, which indicates a mechanical Fig. 2 Individualized PEEP and perioperative management process. iPEEP individualized positive end-expiratory pressure, Cstat-iPEEP optimal static lung compliance-directed iPEEP titration group, EIT-iPEEP electrical impedance tomography-guided iPEEP titration group, RM the ventilator-driven alveolar recruitment maneuver Fig. 3 The ventilator-driven alveolar recruitment maneuver protocol. Ppeak peak airway pressure. Pplat plateau airway pressure. PEEP positive endexpiratory pressure, Vt tidal volume normalized for adjusted body weight, I:E ratio between inspiratory and expiratory time, RR respiratory rate In the Cstat-iPEEP group, patients' iPEEP is obtained through the following procedure (Fig. 5 ): 1. The first RM (RM1) is performed 5 min after intubation. 2. Limit the peak airway pressure to lower than 55 cmH 2 O. 3. V T is fixed to 7ml/kg (predicted body weight, PBW), I: E to 1:1, respiratory rate to 12-15 breaths/ min. 4. Titration procedure: Immediately after the establishment of pneumoperitoneum, PEEP titration is started. Initial PEEP is set to 5 cmH 2 O. PEEP is increased at steps of 2 cmH 2 O, and each PEEP level is sustained for 3 min, during which Cstat is calculated (in accordance with the formula: Cstat = V T /Plat-PEEP). We end the titration process the moment the calculated Cstat displays a downward trend and choose its previous PEEP (the PEEP that maximizes Cstat) as the optimal PEEP for this patient. 5. The upper limit of PEEP is set to 20 cmH 2 O. 6. After the ideal PEEP is obtained, we perform the second RM2. 7. The third RM3 is performed before extubation. The primary endpoint of the study is the amount of calculated atelectasis, corresponding to the percentage of collapsed lung mass, which is obtained through the following steps. The baseline lung volume and its associated parameters of all patients are measured before and after anesthesia induction by Drager's EIT. Immediately after extubation and 2 h postoperation, the proportion taken up by collapsed lung mass is measured by EIT. The amount of atelectasis is calculated via dividing the area occupied by non-ventilated lung mass by baseline lung volume. Secondary endpoints consist of the value of individualized PEEP, oxygenation index (PaO 2 /FiO 2 ), respiratory parameters, blood gas analysis indicators, anesthesiaassociated parameters, and hygienic index. the third RM and before extubation (T1), arterial blood is drawn, blood gas analysis is performed, and oxygenation index is calculated. 3 ] , and/or purulent sputum). 8) Aspiration pneumonitis (respiratory failure resulting from inhalation of regurgitated gastric contents). 9) Pleural effusion (one of the following demonstrated by chest X-ray: blunting of the costophrenic angle, loss of the sharp silhouette of the ipsilateral hemidiaphragm in the upright position, evidence of adjacent anatomical structures displacement, or [in supine position] a hazy opacity in one hemithorax with preserved vascular shadows). 10) Atelectasis (lung opacities with a shift of the hilum, mediastinum, or hemidiaphragm toward the affected area, along with compensatory overdistension in the adjacent nonatelectatic lung). 11) Cardiopulmonary edema (clinical signs of congestion, including dyspnea, edema, rales, and jugular venous distention, with chest X-ray demonstrating an increase in vascular markings and diffuse alveolar interstitial infiltrates). 12) Pneumothorax (air in the pleural cavity, without vascular bed around the visceral pleura). Patients conforming to one of the above conditions are deemed as positive for PPCs. We visit patients preoperatively, intraoperatively, and postoperatively on postoperative days 1 and 3 and at discharge (Table 1) . At all the above-listed points in time, patients' data are collected and recorded. As participation in the study is voluntary, all subjects are free to withdraw their consent to participate in the trial at any time and for any reason without any further treatment or any consequences. Moreover, participation of any subjects could be terminated by an investigator at any time, if he or she believes it is in the best interest of the subject. We shall document the reasons and circumstances of the study discontinuation in the CRF. The primary endpoint of this study is the ratio of collapsed lung mass to normal lung tissue, which is measured and automatically calculated via using EIT before anesthesia and immediately after endotracheal extubation. According to our pre-experimental results of this study, the lung collapse area in the Cstat-PEEP group was 6.5%, while that in the EIT-PEEP group was 6.2%. We apply a noninferiority test. We hypothesize that compared with the ratio of lung collapse area in the EIT-PEEP group, the ratio of lung collapse area in the Cstat-PEEP group will increase by no more than 2% (i.e., the ratio of lung collapse area in Cstat-PEEP group within 8.2% is non-inferior). We choose a two-sided significance level of 0.025 (α) and β= 0.2, with a power of 80%. Using the PASS 11.0 software, a sample size of 64 is calculated for each group. Taking a 10% dropout rate in patients' follow-up into account, a final sample size of 70 is required for each group. The trial is organized by a team comprised of a principal investigator, a general investigator, and other Table 1 Standard protocol items: time schedule of enrollment, interventions, and assessments PNP pneumoperitoneum period, POD1 postoperative day 1, POD3 postoperative day 3, PEEP positive end-expiratory airway pressure, iPEEP individual PEEP, RM recruitment maneuver, EIT electrical impedance tomography, PNP pneumoperitoneum, PPCs postoperative pulmonary complications, POD postoperative day, ICU intensive care unit participants who take part in the design and implementation of the study. For quality control purposes, an external independent physician not involved in the trial will be responsible for data monitoring. Monitoring includes assessment of the progress of the study and verification of accuracy as well as the completeness of recorded data. After completion of the study, we will submit the original data and results to the scientific management committee, and after the publication of results, we will disclose original data and results to the public. After completing the trial, the research team will collaborate with medical statisticians to analyze the data. Statistical analysis will be performed on the basis of intention to treat. SPSS 20.0 software will be used for analysis. The majority of data will be collected and recorded onto the CRF. Before analyzing the data, the pattern of missing data will be evaluated. Analyzation of graphics and data acquired from the EIT machine will be executed by a computer expert familiar with machine principles. Kolmogorov-Smirnov analysis will be used to detect the distribution of all the data. Normally distributed data will be expressed by the mean and standard deviation (SD), while skewed data will be expressed by their median and interquartile range. Unpaired t test will be used for univariate analysis of normally distributed data. Pearson correlation test will be employed to test the correlation between two variables. Mann-Whitney U test and Wilcoxon signed-rank test will be applied for skewed data. Categorical variables will be assessed by Fisher's exact test, chi-square tests, or relative risk, if appropriate. 95% CI will be employed to express statistical uncertainty. P value <0.05 shall be regarded as significant. This trial is sufficiently powered to test the hypothesis that an individualized PEEP titrated by maximizing Cstat is not inferior to individualized PEEP determined by EIT in terms of lowering the proportion of collapsed lung tissue, for obese patients. The result will prove that the method of best Cstat titration iPEEP is simple and effective in clinical practice. According to a population-based study, in 2014, approximately 10.8% of men and 14.9% of women are obese globally [13] . In obese patients, the respiratory compliance is further limited by the cephalic movement of the diaphragm. In addition, the FRC and alveolar ventilation volume of obese patients are much lower than their non-obese counterparts. The incidence of atelectasis in obese patients under general anesthesia is as high as 90% [14] . In obese patients under general anesthesia and mechanical ventilation, the proportion of normal ventilated lung tissue drops from 71 to 50%, while the proportion of insufficiently ventilated lung mass increases from 28 to 39%, and the proportion of nonventilated lung tissue elevates from 1 to 11%. In sharp contrast, the proportion of atelectatic lung mass is only 3% in normal weight patients under general anesthesia and mechanical ventilation [15] . Because airway pressure required to keep lung units from collapsing is much lower than the pressure needed to recruit atelectatic lung units, recruitment maneuver could significantly improve ventilation. Applying PEEP after a successful recruitment maneuver could prevent the rapid reformation of atelectasis, especially when the fraction of inspired oxygen is as high as 100% [16] . Applying PEEP alone alleviates the reduction of endexpiratory lung volume and lung elastance imposed by pneumoperitoneum on obese patients, but fails to reduce an atelectatic fraction of the lung tissue [17] . Compared to PEEP applied alone, the combination of PEEP and recruitment maneuver leads to greater enhancement in lung elastance and results in lower airway pressure as well as resistance in obese patients undergoing laparoscopic surgery. However, no agreement has been reached concerning the optimal PEEP for obese patients. High PEEP is associated with improved intraoperative oxygenation and lung elastance as well as a reduced proportion of atelectatic lung units, especially for obese patients [18] . But too high PEEP may lead to overextension of lung units, which aggravate lung injury. From the PROBESE study, compared to a lower PEEP, a fixed higher PEEP did not decrease the incidence of PPCs in obese patients [1] . According to the literature, it is highly unlikely to find a fixed PEEP which suits all patients with significant variation in PEEP requirement caused by individual characteristics, such as abdominal content, chest wall shape and dimensions, pleural pressures, and lung weights [19] . Thus, an individualized ideal PEEP may be superior to a fixed PEEP level. Relevant studies have discovered that compared with applying a fixed PEEP, applying individualized PEEP improves oxygenation and respiratory compliance, reduces the fraction of dead space, minimizes atelectasis, optimizes ventilation distribution, and ameliorates lung injury by lowering driving pressure [20, 21] . No consensus has been reached concerning the ideal way to select the ideal and individualized PEEP. And, many ways effective for selecting individualized PEEP for normal weight patients may not be appropriate for obese patients. For instance, determining individualized PEEP as the pressure nearest to the low inflection point of the pressure-volume curve underestimates the PEEP required by obese patients [22] . Electrical impedance tomography (EIT) is deemed superior to traditional ways of individualized PEEP titration by many studies [23, 24] . EIT is a clinical imaging tool that monitors local ventilation distribution. It enables the continuous measurement of local lung ventilation changes resulting from the application of recruitment maneuvers and PEEP as well as adjustments in tidal volume and fraction of inspired oxygen. Traditional ways of PEEP titration may provide misleading information by averaging contradicting pathological characteristics of different lung units, such as overdistention and atelectasis. In contrast, EIT monitors regional lung ventilation and can detect pulmonary heterogeneity in a dynamic process. It has gained widespread interest in guiding lung-protective ventilation in obese patients. However, the EIT instrument is unaffordable by many clinical institutions, which limits its use in routine clinical practice. At the same time, the bandage of the EIT machine conflicts with the field disinfection of many operations in the chest or abdomen, which also limits its application in the perioperative period. So alternative ways to titrate PEEP both affordable and effective need to be found out. This study is going to test the efficacy of determining individualized PEEP during an incremental titration procedure guided by optimal static lung compliance by comparing it with the PEEP titration strategy directed by EIT. In our previous study [25] , it has been found that when applying optimal static lung compliance titration iPEEP in obese patients undergoing laparoscopic surgery, the PEEP value was about 10.5 cmH 2 O. Compared with PEEP 5 cmH 2 O, it could significantly improve the oxygen index and respiratory function of obese patients during and after laparoscopic surgery, combined with other lung protective strategies. These data provide evidential support for us to use the best static lung compliance method to titrate iPEEP. In conclusion, this study aims to verify the following hypothesis: individualized iPEEP titrated to optimal static lung compliance is not inferior to individualized iPEEP obtained during a titration procedure guided by EIT, in terms of improving intraoperative oxygenation and ameliorating postoperative atelectasis in obese patients undergoing laparoscopic surgery. This study will provide a convenient and feasible strategy for individualized PEEP titration in obese patients. The result shall provide direct evidence to further refine lung-protective ventilation strategies in obese patients and exploit the significance of lung-protective ventilation in ERAS in obese patients. We enrolled the first participant of the trial on November 15, 2020, the protocol version is the first version, and the version number is V1.0/2020.06.26. We will complete the recruitment on September 17, 2022. This trial is still ongoing. Abbreviations PPCs: Postoperative pulmonary complications; iPEEP: Individualized positive end-expiratory pressure; Cstat: Static lung compliance; FiO2: Inspiratory fraction of inspired oxygen PBW: Predicted body weight; RM: Recruitment maneuvers; VT: Tidal volume CRF: Case report forms; ARISCAT: The assess respiratory risk in surgical patients in catalonia; BMI: Body mass index; COPD: Chronic obstructive pulmonary disease; Cstat-iPEEP: Optimal static lung compliance-directed iPEEP titration group; EIT-iPEEP: Electrical impedance tomography-guided iPEEP titration group; VAS: Visual analog scale; PSC-VC: Pressure-controlvolume compensation mode PaO 2 : Partial pressure of arterial oxygen Effect of intraoperative high Positive End-Expiratory Pressure (PEEP) with recruitment maneuvers vs low PEEP on postoperative pulmonary complications in obese patients: a randomized clinical trial Epidemiology, practice of ventilation and outcome for patients at increased risk of postoperative pulmonary complications: Las Vegas-an observational study in 29 countries Postoperative pulmonary complications, early mortality, and hospital stay following noncardiothoracic surgery: a multicenter study by the perioperative research network investigators Estimate of the global volume of surgery in 2012: an assessment supporting improved health outcomes Lung-protective ventilation for the surgical patient: international expert panel-based consensus recommendations Effect of intraoperative low tidal volume vs conventional tidal volume on postoperative pulmonary complications in patients undergoing major surgery: a randomized clinical trial Intraoperative ventilation settings and their associations with postoperative pulmonary complications in obese patients Individualized positive end-expiratory pressure in obese patients during general anaesthesia: a randomized controlled clinical trial using electrical impedance tomography Protective intraoperative ventilation with higher versus lower levels of positive endexpiratory pressure in obese patients (PROBESE): study protocol for a randomized controlled trial Comparison of World Health Organization and Asia-Pacific body mass index classifications in COPD patients Intraoperative protective mechanical ventilation for prevention of postoperative pulmonary complications: a comprehensive review of the role of tidal volume, positive end-expiratory pressure, and lung recruitment maneuvers Individual positive end-expiratory pressure settings optimize intraoperative mechanical ventilation and reduce postoperative atelectasis Trends in adult body-mass index in 200 countries from 1975 to 2014: a pooled analysis of 1698 population-based measurement studies with 19.2 million participants Transpulmonary pressure describes lung morphology during decremental positive end-expiratory pressure trials in obesity Prevention of atelectasis in morbidly obese patients during general anesthesia and paralysis: a computerized tomography study Strategies for managing oxygenation in obese patients undergoing laparoscopic surgery Intraoperative recruitment maneuver reverses detrimental pneumoperitoneum-induced respiratory effects in healthy weight and obese patients undergoing laparoscopy Intraoperative mechanical ventilation strategies for obese patients: a systematic review and network meta-analysis Recruitment maneuvers and positive end-expiratory pressure titration in morbidly obese ICU patients Assessment of ventilation distribution during laparoscopic bariatric surgery: an electrical impedance tomography study Effects of intraoperative positive end-expiratory pressure optimization on respiratory mechanics and the inflammatory response: a randomized controlled trial Should PEEP titration be based on chest mechanics in patients with ARDS? Respir Care Chest electrical impedance tomography examination, data analysis, terminology, clinical use and recommendations: consensus statement of the TRanslational EIT developmeNt stuDy group Positive end-expiratory pressure titration with electrical impedance tomography and pressure-volume curve in severe acute respiratory distress syndrome Effects of intraoperative individualized PEEP on postoperative atelectasis in obese patients: study protocol for a prospective randomized controlled trial Publisher's Note Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations Here, we sincerely thank the doctors and nurses in the surgical ward of the Beijing Friendship Hospital for their assistance and cooperation. The online version contains supplementary material available at https://doi. org/10.1186/s13063-021-05671-1. Authors' contributions ALX is the chief investigator. She is responsible for the quality control of the topic selection, design, project implementation, and paper revision; WQY and JYW are both responsible for the performing of this study and the writing of this manuscript; CL is responsible for the clinical anesthesia and case collection; XFS is responsible for the English revision. The authors read and approved the final manuscript. This study did not receive any internal or external funding. Data will be disclosed to the public after the complication of the trial. After the study is completed and the results are published, the data will be obtained by contacting the corresponding author. Ethics approval and consent to participate The study has obtained ethics approval from the Ethics Committee of Beijing Friendship Hospital affiliated to the Capital Medical University (The approval number is 2020-P2-145-01). All enrolled patients fulfilling the inclusion criteria are required to provide written informed consent the day prior to surgery. Subjects have the right to withdraw their consent any time during the trial. Not applicable. The authors declare that they have no competing interests.