Intraoperative mechanical ventilation and incidence of pneumothorax in lymphangioleiomyomatosis

Patients with lymphangioleiomyomatosis (LAM) are considered high risk for most surgeries and require specific anesthetic considerations mainly because of the common spontaneous pneumothorax (PTX). To explore whether intraoperative mechanical ventilation could increase the risk of PTX in those patients, we included 12 surgical patients with LAM in this study, of whom four (33.3%) experienced postoperative PTX. According to our results, patients with higher CT grade, poorer pulmonary function, and a history of preoperative PTX might be more likely to develop postoperative PTX. However, intraoperative mechanical ventilation did not show obvious influence, which might help clinicians reconsider the perioperative management of LAM patients.

Lymphangioleiomyomatosis (LAM) is a rare disease affecting almost exclusively women in reproductive age. It is characterized by the proliferation of abnormal smooth muscle-like cells (LAM cells) in the lungs and lymphatic system, and is considered as a low-grade metastasizing neoplasm [1,2,3]. In the lungs, LAM cell proliferation leads to the development of multiple thin-walled cysts and progressive destruction of the parenchyma, resulting in dyspnea, obstructive ventilatory, reduced carbon monoxide transfer factor, and hypoxemia [4]. Pneumothorax (PTX) is a common manifestation of LAM. Previous studies have demonstrated that approximately 66% of patients with LAM may exhibit pneumothorax; importantly, 70% of these patients may experience recurrent ipsilateral or contralateral pneumothoraces [5]; therefore, these patients are considered high risk for most surgeries and require specific considerations for anesthesia [6]. Several studies, mostly case reports, have discussed perioperative management strategies for LAM patients and recommended regional anesthesia to prevent the rupture of closed lung cysts and further PTX [7]. However, regional anesthesia may be not suitable for all procedures, and patients inevitably need positive pressure ventilation under general anesthesia in certain situations. Considering this, we hope to explore whether intraoperative mechanical ventilation could increase the incidence of PTX in patients with LAM.

This study was approved by the Institutional Review Board of Peking Union Medical College Hospital (K2197). We retrieved all the surgical patients diagnosed with LAM in Peking Union Medical College Hospital through Anesthesia Information Management System between January 2013 and June 2022. The diagnosis of LAM was based on the American Thoracic Society and Japanese Respiratory Society guidelines published in 2017 [8]. The primary outcome was new or recurrent PTX within 30 days after surgery (including intraoperative period), confirmed by radiological imaging of the chest. Data including demographics, preoperative variables and intraoperative variables were reviewed. For preoperative variables, the high-resolution computerized tomography (CT) grade of LAM (classified according to the proportion of cystic lesions in the total lung), vascular endothelial growth factor-D (VEGF-D) level, pulmonary function, 6-min walking distance (6MWD), history of PTX, history of pleurodesis, menstruation and pregnancy status, as well as mammalian target of rapamycin (mTOR) inhibitor therapy were analyzed. Among them, high-resolution CT, VEGF-D level, 6MWD, and pulmonary function were all tested within 30 days before surgery. As for intraoperative variables, the surgical type, anesthetic technology, surgical and anesthetic duration and mechanical ventilation were reviewed. Because of the small number of patients involved in this retrospective study, a description of cases was used, while we still tried to conduct the descriptive statistics as an exploratory analysis. A 2-sided P value less than 0.05 was considered the threshold for statistical significance.

We finally included 12 surgical patients with a definite diagnosis of LAM. They were all females with a mean age of 41 ± 10 years, among whom four (33.3%) experienced PTX within 30 days after surgery (three recurrent and one new case, no intraoperative PTX). As shown in Table 1, more patients had high CT grade (III) in postoperative PTX group (PP group) than no postoperative PTX group (nPP group) (66.7% vs. 37.5%). Patients in the PP group showed poorer pulmonary function compared to those in the nPP group (FEV₁%pred 69.5 ± 7.8% vs. 79.1 ± 28.7%, DLco%pred 36.0 ± 15.6% vs. 66.3 ± 29.9%, PaO₂ 71.4 ± 10.2 mmHg vs. 84.5 ± 13.3 mmHg, SpO₂ 93 ± 6% vs. 98 ± 2%). 75% of patients in PP group had a history of spontaneous PTX before surgery, while only 37.5% in nPP group. A total of three patients received preoperative mTOR inhibitor therapy. In one patient, everolimus (5 mg, Qd) was taken for 2.5 months and stopped 15 days before surgery due to the herpes zoster. The second patient had received sirolimus (1 mg, Qd) therapy since 23 days before surgery. The third patient had been treated with sirolimus (1 mg, Qd) for 9 years, and stopped 28 days before surgery. All three patients did not develop postoperative PTX, and two of them received intraoperative mechanical ventilation. However, there is no significant difference between the two groups according to the statistical analysis (Suppl 1).

As for intraoperative variables, however, there was little difference between the two groups in whether patients underwent pulmonary surgery, received general or regional anesthesia, and experienced mechanical ventilation. The parameters of mechanical ventilation (mean peak airway pressure and respiratory rate) and whether intensive care unit (ICU) without extubation did not different either. The duration of mechanical ventilation in PP group patients was significantly prolonged (P = 0.002), which may be related to one patient who developed postoperative PTX during ICU admission before extubation and continued mechanical ventilation for several days (Table 1, Suppl 1).

For the four patients developing postoperative PTX, detailed information is listed in Table 2. As we can see, the postoperative PTXs all occurred in more than one week after the surgery - postoperative days (POD) 10, POD 20, POD 13 and POD 8, respectively. Most patients showed II to III of CT grades and poor pulmonary ventilation and diffusion capability. Three patients had preoperative PTX and even recurrent PTXs, and no patients had been treated with mTOR inhibitors before surgery. Two patients underwent pulmonary surgery, and another two underwent cesarean section. Three patients received general anesthesia and experienced mechanical ventilation during the surgery, with two extubated successfully after surgery and one back to ICU without extubation. One patient received regional anesthesia and did not experience intraoperative mechanical ventilation.

From our results, preoperative factors seem more important for the risk evaluation of LAM. Patients with higher CT grade, poorer pulmonary function (both ventilation and diffusion function), and a history of preoperative PTX might be more likely to develop postoperative PTX, consistent with previous research [9]. However, the intraoperative factors, especially mechanical ventilation that we usually concerned, did not show obvious effect on postoperative PTX, as we imagined. These findings might indicate that for patients with well-controlled preoperative conditions, intraoperative mechanical ventilation may not increase the risk of postoperative PTX. Higher PaO₂ and SpO₂ on room air may also convey a safer message for mechanical ventilation if patients are unsuitable for pulmonary function testing. Consistent with the potential protective effect of mTOR inhibitors in LAM patients [10], patients with preoperative mTOR inhibitor therapy in our study did not experience postoperative PTX even under mechanical ventilation.

According to previous research, appropriate protective ventilation strategies, such as lower positive end expiratory pressure, no recruitment maneuvers and nitrous oxide, and pressure-controlled or pressure-regulated volume-controlled ventilation, are recommended in general anesthesia for LAM patients to prevent PTX [6]. However, our results suggest that those with poor preoperative conditions may still be at high risk of postoperative PTX regardless of whether mechanical ventilation is used and what ventilation strategies are chosen during surgery. For such patients, controlling the progress of disease and improving pulmonary function before surgery might be more essential.

In our study, half of the patients underwent pulmonary surgery. Since some postoperative PTXs are related to pulmonary procedure itself, this might greatly bias the risk of postoperative PTX. However, postoperative PTX in this study all occurred in more than one week after the surgery, which were more likely to be disease-related rather than procedure-related. On the other hand, the incidence of postoperative PTX was quite the same in patients receiving pulmonary and non-pulmonary surgery (33.3%), and the proportion of patients undergoing pulmonary and non-pulmonary surgery in PP group was also the same (50.0%). In addition, according to the information shown in Suppl 2, patients received lobectomy or pleurodesis mainly because of recurrent spontaneous PTX or in order to make a definite diagnosis, and those who with good preoperative conditions did not develop postoperative PTX even undergoing pulmonary surgery. Therefore, the bias of pulmonary surgery on the risk of postoperative PTX may be not large, but this inference may not be generalized in a larger population considering the limited sample size.

Although we included as many surgical patients with LAM as possible in this study, the sample size was still small due to the extremely low prevalence of LAM (3.4 to 7.8 per million women) [11], and thus limited the power of statistical analysis. Despite no specific conclusion could be drawn from these 12 patients, our results indeed help clinicians reconsider the perioperative management of LAM patients. Whether intraoperative mechanical ventilation could increase the risk of PTX for patients with LAM might depend more on patients’ preoperative conditions, especially the CT grade, pulmonary function, history of spontaneous PTX, and mTOR inhibitor therapy. Further studies with larger sample sizes and including more detailed mechanical ventilation parameters are needed to verify our findings and discover more information about the perioperative management of patients with LAM.

The datasets generated and/or analyzed during the current study are not publicly available due to IRB restrictions. Data can be made available from the corresponding author on reasonable request and with the appropriate IRB approvals.

ASA:

American Society of Anesthesiologists

CSEA:

Combined spinal and epidural anesthesia

CT:

Computerized tomography

DLco:

Diffusing capacity for carbon monoxide

FEV₁ :

Forced expiratory volume in 1 s

GA:

General anesthesia

ICU:

Intensive care unit

LAM:

Lymphangioleiomyomatosis

mTOR:

Mammalian target of rapamycin

nPP group:

Patients who did not develop postoperative pneumothorax

PaO₂ :

Partial pressure of oxygen in arterial blood

POD:

Postoperative days

PP group:

Patients who developed postoperative pneumothorax

PTX:

Pneumothorax

SpO₂ :

Room air pulse oxygen saturation

TSC:

Tuberous sclerosis complex

VATS:

Video-assisted thoracoscopic

VEGF-D:

Vascular endothelial growth factor-D

6MWD:

6-min walking distance

We would like to thank the Department of Obstetrics and Gynecology, Urology, and Thoracic Surgery of Peking Union Medical College Hospital for supporting this study.

This work was supported by the Chinese Academy of Medical Sciences Innovation Fund for Medical Sciences (CIFMS 2021-I2M-1-003) and the National Natural Science Foundation of China (U20A20341).

Authors and Affiliations

1. Department of Anesthesiology, Peking Union Medical College Hospital, Chinese Academy of Medical Sciences, Beijing, China

   Chen Sun, Lijian Pei, Bing Bai & Yuguang Huang

2. Department of Pulmonary and Critical Care Medicine, Peking Union Medical College Hospital, Chinese Academy of Medical Sciences, Beijing, China

   Chongsheng Cheng & Kai-Feng Xu

3. State Key Laboratory of Complex Severe and Rare Diseases, Peking Union Medical College Hospital, Chinese Academy of Medical Sciences, Beijing, China

   Lijian Pei, Chongsheng Cheng, Kai-Feng Xu & Yuguang Huang

4. Outcomes Research Consortium, Cleveland, OH, USA

   Lijian Pei

Contributions

Study design: CS, LP, KFX. Acquisition, analysis or interpretation of the data: CS, LP, CC, BB, KFX, YH. Statistical analysis: CS, CC. All authors contributed to the critical revision of the manuscript for important intellectual content. All authors reviewed and approved the final manuscript.

Corresponding authors

Correspondence to Lijian Pei or Kai-Feng Xu.

Ethics approval and consent to participate

This study was approved by the Institutional Review Board of Peking Union Medical College Hospital (K2197). Written informed consent was obtained from all subjects involved. All methods were carried out in accordance with institutional guidelines and regulations.

Consent for publication

Not applicable.

Competing interests

The authors declare that they have no competing interests.

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