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Indications of airway stenting for severe central airway obstruction due to advanced cancer

  • Hiroaki Nagano ,

    Contributed equally to this work with: Hiroaki Nagano, Tomoo Kishaba

    hiroakinoko322violin@gmail.com

    Current address: 281 Miyazato, Uruma-City, Okinawa Pref, Japan

    Affiliation Department of Respiratory Medicine, Okinawa Chubu Hospital, Okinawa, Japan

  • Tomoo Kishaba ,

    Contributed equally to this work with: Hiroaki Nagano, Tomoo Kishaba

    Affiliation Department of Respiratory Medicine, Okinawa Chubu Hospital, Okinawa, Japan

  • Yuichirou Nei ,

    ‡ These authors also contributed equally to this work.

    Affiliation Department of Respiratory Medicine, Okinawa Chubu Hospital, Okinawa, Japan

  • Shin Yamashiro ,

    ‡ These authors also contributed equally to this work.

    Affiliation Department of Respiratory Medicine, Okinawa Chubu Hospital, Okinawa, Japan

  • Hiroaki Takara

    ‡ These authors also contributed equally to this work.

    Affiliation Department of Radiology, Okinawa Chubu Hospital, Okinawa, Japan

Abstract

Background

Management of severe central airway obstruction due to advanced cancer is a medical and technical challenge. The impact of airway stenting on the clinical outcome of such patients is unclear.

Method

This single-center, retrospective study evaluated 21 patients who underwent airway stenting for advanced cancer. We examined predictors of the post-stenting mortality, including age, serum albumin, tracheal diameter, smoking, opioid use, respiratory failure, and performance status (PS). We also compared survival according to the PS.

Results

The mean survival period after stenting was 85.2 days. On univariate analysis, age, albumin, PS before airway stenting, respiratory failure, admission route, and PS grade were the candidates as possible predictors of prognosis after the procedure. On multivariate analysis, PS before airway stenting was identified as possible predictor of prognosis after stenting (HR 1.6180, 95% CI 0.969 to 2.7015, p = 0.066). The mean survival period after stenting was significantly longer in the good PS group, compared to the poor PS group (147.8 days vs. 38.2 days,p = 0.0346).

Conclusion

Airway stenting for advanced cancer may be more effective for patients in good general condition than in those with poor performance status.

Introduction

For pulmonologists, helping patients who have severe central airway obstruction (CAO) due to unresectable advanced cancer is a challenge because the condition can deteriorate anytime and lead to choking and sudden death. Dyspnea due to airway stenosis is an intolerable symptom for these patients [1]. Airway stenting is one of the options to relieve airway obstruction. However, the patient characteristics associated with the best outcomes after airway stent insertion remain to be defined [2,3].

We sometimes have the consult about the indication of tracheal stent insertion. Since there are no global standard guidelines, we often face the situations which is difficult to decide whether stent insertion benefit patients.

In the previous report, there are some conditions for stent placement [4]. However, these criteria are empirical and their evidence level is low.

The aim of this study was to evaluate the factors associated with mortality after airway stenting and to assess the outcome and efficacy of airway stenting for malignant CAO.

Materials and methods

Data collection

We retrospectively reviewed the medical records of patients who underwent airway stent insertion for severe airway obstruction caused by malignant tumor compression or invasion at our institution from January 1, 1998 to March 31, 2015. We investigated the patients’ background such as gender, age, smoking rate, primary organ, treatment before and after stenting, laboratory data, opioid use, airway diameter and procedure time. We investigated airway stenting outcomes, such as survival after stenting, discharge rate, and improvement of oxygenation.

We also focused on the patient’s performance status (PS), tried to investigate whether it affected survival or symptom palliation. The study population was divided into good PS (PS:0–2) and poor PS (PS: 3–4) groups. The reason why we divided patients into two groups is most chemotherapy regimens are not recommended for PS 3 and PS 4 patients in NCCN (National Comprehensive Cancer Network) guideline [5]. When we considered something invasive treatment for cancer, we decided that grouping of PS 0–2 and 3–4 is generally reasonable. Grouped PS was defined to analyze how each PS group (PS 0–2 and PS 3–4) was related to the patients’ survival.

Airway stenting

In all patients, metallic airway stents were used. Before procedure, benzodiazepines were used for sedation. Morphine was used for analgesia. After careful inspection of the tracheal lumen, the pulmonologists deployed the stent by flexible bronchoscopy. With the cooperation of the radiologists, the position of the airway stent was adjusted to the appropriate location under X-ray guidance “Fig 1”.

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Fig 1. Airway stenting by metallic stent.

(A) Tracheal compression from advanced esophageal cancer producing marked tracheal compression and critical airway stenosis. (B) Palliation by placement of tracheal Spiral Z stent producing immediate resolution of airway symptoms.

https://doi.org/10.1371/journal.pone.0179795.g001

Performance status, respiratory failure, oxygenation

The Eastern Cooperative Oncology Group Performance Status (PS) scores that were gathered from medical and nursing records were used to evaluate the activities of daily living of each patient [6]. Grade 0 was defined as fully active, able to carry on all pre-disease performance without restriction. Grade 1 was defined as restricted in physically strenuous activity, but ambulatory and able to carry out any work of light or sedentary nature. Grade 2 was defined as ambulatory and capable of all self-care, but unable to carry out any work activities; up and about for more than 50% of waking hours. Grade 3 was defined as capable of limited self-care only; confined to bed or chair for more than 50% of waking hours. Grade 4 was defined as completely disabled; cannot perform any self-care; totally confined to bed or chair. The study population was divided into good PS (PS:0–2) and poor PS (PS: 3–4) groups.

Respiratory failure was defined as severe dyspnea, respiratory distress, decreased oxygen saturation (less than 90% on room air), hypoxemia with PaO2<60mmHg, on room air, or requiem of noninvasive or invasive mechanical ventilation. The improvement of oxygenation was defined as the improvement of PaO2 on arterial blood gas, or decreased oxygen requirement.

Mortality

Mortality was defined as survival two months after the stent insertion. This is because the mean survival period after stenting was 85.2 days.

Ethics committee approval

The Ethics Committee of Okinawa Chubu Hospital approved the study protocol. Informed consent was waived because this study was a retrospective, epidemiologic, and anonymous review of medical records, rather than a prospective, interventional clinical study.

Statistical analysis

Clinical data were presented as mean, depending on the distribution. Variables, such as clinical background, mean survival period, rate of discharge to home, post-procedure PS, improvement of oxygenation, and death from pneumonia, were compared between the good and poor PS groups using a X2 test. Univariate and Multivariate analysis with a Cox proportional hazards model was used to determine the relationships between the clinical parameters and survival after the procedure, as well as survival according to PS. We chose the objects for multivariate analysis which p-value were under 0.1 in univariate analysis. The level of statistical significance was set at P <0.05. STATA software V.11.0 (Stata Corp., College Station, TX, USA) was used for all statistical analyses.

Results and discussion

Clinical characteristics

This 15-year study included 21 patients who underwent airway stenting for malignant CAO. The study population had a mean age of 66.1 years and comprised 3 (14.3%) women and 17 (81.0%) patients who were smokers. The cause of CAO was esophagus cancer in 10 (50.0%), lung cancer in 7 (33.3%), metastatic lung cancer in 2(9.53%), malignant mesothelioma in 1 (4.76%) and hypopharyngeal cancer in 1(4.76%).

The classification of pathology was squamous cell carcinoma in 16 (76.2%), adenocarcinoma in 2 (9.5%), small cell carcinoma in 2 (9.5%), and malignant mesothelioma in 1 (4.8%). There were 10(47.6%)patients who had chemotherapy, 7(33.3%)patients who had radiation therapy before procedure. 2(9.5%) patients had both chemotherapy and radiation therapy before and after airway stent insertion. The rate of patients who had radiation therapy before procedure was significantly higher in good PS group than that of patients in poor PS group (66.7% vs 8.3%, p = 0.019). There were 7(33.3%) patients who underwent surgery before procedure, and there were no patients who had surgery after stent insertion.

There were 14 (66.7%) patients admitted to the hospital from the emergency department. The good PS group (n = 9) and poor PS group (n = 12) had similar background characteristics, such as gender, age, smoking rate, and laboratory data other than radiation therapy before procedure (Table 1).

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Table 1. Background of patients who underwent airway stenting for malignant obstruction.

https://doi.org/10.1371/journal.pone.0179795.t001

Prognosis after the procedure

The mean survival period after stenting was 85.2 days. 13 (61.9%) experienced relief of dyspnea or improved oxygenation; and 11 (52.4%) patients were discharged to home after stenting. On univariate analysis,age, albumin, PS before airway stenting, respiratory failure, admission route, and group PS were the candidates as possible predictors of prognosis after the procedure. Other factors, such as age, gender, serum albumin, respiratory failure, admission route did not predict mortality after airway stenting. The treatments for cancer such as chemotherapy, radiation therapy and surgery also did not predict mortality on univariate analysis.(Table 2).

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Table 2. Cox proportional hazards regression analysis of mortality after airway stenting: Univariate analysis.

https://doi.org/10.1371/journal.pone.0179795.t002

On multivariate analysis,PS before airway stenting was identified as possible predictor of prognosis after the procedure (HR 1.6180, 95% CI 0.969 to 2.7015, p = 0.066). Grouped PS was also the candidate as possible predictor of prognosis because of high HR (HR 3.1555, 95% CI 0.8550 to 11.6459, p = 0.085) (Table 3).

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Table 3. Cox proportional hazards regression analysis of mortality after airway stenting: Multivariate analysis.

https://doi.org/10.1371/journal.pone.0179795.t003

The mean survival period after the procedure was significantly longer in the good PS group, compared to the poor PS group (147.8 days vs. 38.2 days,p = 0.0346). The discharge rate after the procedure was higher in the good PS group than the poor PS group (77.8% vs. 33.3%; p = 0.0457). Improvement of oxygenation after stenting showed no statistically significance between good PS group and poor PS group (77.8% vs. 50.0%.p = 0.5181) (Table 4).

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Table 4. Outcomes of airway stenting for malignant obstruction.

https://doi.org/10.1371/journal.pone.0179795.t004

Of the 21 patients, 9 (42.9%) died of infectious pneumonia and 4 (19.0%) died due to cancer progression. Other causes of death were massive hemoptysis caused by trachea-artery fistula, pneumothorax, myocardial infarction, mucus plug, and other unknown factors.

Weaning from mechanical ventilation.

Of all patients, 9 (42.9%) were intubated before airway stenting; 7 of 9 (77.8%) were successfully extubated after stenting. Five patients underwent elective intubation during airway stenting, 2 could not be extubated post-stenting and eventually died (Table 5).

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Table 5. Weaning from mechanical ventilation after airway stenting for malignant obstruction.

https://doi.org/10.1371/journal.pone.0179795.t005

Discussion

For patients who have advanced cancer, quality of life is as important as survival [7,8]. Our duty and sincere intention as clinicians is to alleviate disabling dyspnea, obstructive pneumonia, and acute suffocation in patients with malignant airway obstruction. Depending on the type of malignancy, options for non-surgical palliation and local control of tumor spread include chemotherapy and/or radiotherapy. However, despite chemotherapy and radiotherapy, patients may still develop life-threatening CAO, which might be an appropriate indication for interventional bronchoscopy [1]. Airway stent insertion may provide immediate and gratifying palliation that can rescue patients from imminent death and assure improvement in quality of life [7,9,10,11]. However, the patient characteristics associated with the best outcomes after airway stent insertion are unknown [2,3]. Being an invasive procedure, airway stenting indications have to be considered carefully. In a previous study, Matsuo et al. reported their indications for stent placement, as follows: 1) severe CAO presenting with dyspnea and flow limitation on a flow-volume curve; 2) prognosis will be prolonged by stent placement; and 3) peripheral airways and lungs are otherwise intact [4]. In this present study, only pre-stenting PS was identified by multivariate logistic regression analysis as a potential independent predictor of prognosis after stent insertion. Since we had small number of patients, the p values did not reach statistical significance on multivariate analysis. However, HR of group PS showed high value. Therefore, we thought both PS and before airway stenting and grouped PS tended to show the possible predictor of prognosis after stenting.

Similar to chemotherapy, airway stenting indications might be dictated by a patient’s PS [12]. Based on our results, patients who have good PS may benefit from stenting in terms of longer survival and improved oxygenation. Indeed, stent placement was shown to prevent acute suffocation, alleviate fear of sudden death, and provide patients sufficient time to undergo additional therapies, such as chemotherapy, radiotherapy, and palliative care [11].

Care must be taken in choosing the indications of airway stenting in patients with poor PS. Although the severe symptoms of dyspnea can be alleviated by stent insertion, survival after the procedure might not be prolonged. Before the procedure, the limitations and temporary effects of stenting must be disclosed. The choice of airway stent is usually based on operator preference. Removable stents are preferred because long-term complications, such as infection, obstructive granuloma, fistula, and migration, are common [1318]. For this study population, we chose metallic stents because of the radiologists’ experience on metallic stents, as opposed to rigid bronchoscopy with silicone stents [18][19].

In this study, the median survival time after the procedure was quite different from that of previous reports [9,11,13,17,19,20]. This might be due to differences in patients’ general condition and clinical background between our study and the previous reports.

In both groups, there were no major complications during the procedure. However, after the procedure, 9 patients died of pneumonia, which might have been caused by mucus plugging of the stent. One patient died due to massive hemoptysis from a trachea-artery fistula. Although this also may be associated with stent placement, the extent of stent involvement in the bleeding is unknown. [21]

In our study, 75% of the intubated patients were successfully extubated. This result was of great benefit to the patients because they were able to return to the general ward or to be discharged home. In the 2 patients who were intentionally intubated during airway stenting and subsequently died without being extubated, the cause could be an indirect complication of the procedure. One potential complication is sudden suffocation during stent insertion, especially in patients who have extremely severe airway stenosis or edema. For such cases, preparations for extracorporeal membrane oxygenation (ECMO) can be made [2224]. In this study, 2 patients were placed on bypass during airway stent insertion. At present, evidence on the value of these adjuncts during stenting is limited. More discussion and studies that verify the safety, appropriate analgesia, and indications for intubation and ECMO during the airway stenting are needed.

We recognize some limitations of our study. This was a single-center, retrospective, observational study. Without comparison to a placebo group, we were unable to conclude whether airway stenting itself contributed to survival benefit.

From January 1, 1998 to March 31, 2015 is a very long period. Only 21 patients were analyzed during this long period. Much progress has been made for cancer therapy during this period. However, in our study, the treatments for cancer such as chemotherapy, radiation therapy and surgery did not influence on mortality with univariate analysis.

The efficacy of airway stenting depends on appropriate patient selection, anatomic location of the obstruction, and the underlying pathology. Therefore, careful consideration should be given when evaluating the risks and benefits of stenting for each patient [14]. We also have to carry out discussions with the patient and family members, as well as the paramedical staff, regarding fulfillment of each patient’s end of life goals.

Conclusions

The indications for airway stenting in patients with advanced cancer should take into account the patient’s PS, which was the only possible predictor of prognosis after stenting as shown by our study. Airway stenting for advanced cancer may be more effective in patients in good general condition than in patients with poor PS. Attending physicians have to communicate with each patient about his/her life expectancy and evaluate the benefits of airway stenting based on PS.

Acknowledgments

The authors are indebted to Mitsuyo Kinjo of Okinawa Chubu Hospital for her review of this manuscript.

Author Contributions

  1. Conceptualization: HN TK.
  2. Data curation: HN TK.
  3. Formal analysis: HN TK.
  4. Investigation: HN SY YN HT.
  5. Methodology: HN TK.
  6. Project administration: HN TK.
  7. Resources: HN TK.
  8. Software: HN TK.
  9. Supervision: HN TK.
  10. Visualization: HN.
  11. Writing – original draft: HN.
  12. Writing – review & editing: HN TK SY YN HT.

References

  1. 1. Wood Douglas E, Liu Yun-Hen, Vallieres Eric. Airway Stenting for Malignant and Benign Tracheobronchial Stenosis. Annals of Thoracic Surgery. 2003;76:167–174. pmid:12842534
  2. 2. Bolliger CT, Mathur PN, Beamls JF. ERS/ATS statement on intervenetional pulmonology. Eur Respir J. 2002;19:356. pmid:11866017
  3. 3. Ernest A, Silvestri GA, Johnstone D. Interventional pulmonary procedures. Guidelines from the American College of Chest Physicians. Chest. 2003;123:1693. pmid:12740291
  4. 4. Matsuo Keisuke, Watanabe Yoichi, Tamaoki Akihiko. Indispensable Guideline for Airway Stent. The Journal of the Japan Society for Respiratory Endoscopy.2009;29: 26–9.
  5. 5. Ettinger David S, Wood Douglas E., Akerley Wallace, Bazhenova Lyudmila A., Borghaei Hossein, Camidge David Ross et al. National Comprehensive Cancer Network(NCCN) Guidelines Non-Small Cell Lung Cancer Version 7. 2015:32–33
  6. 6. Oken M.M., Creech R.H., Tormey D.C., Horton J., Davis T.E., McFadden E.T., Carbone P.P. Toxicity And Response Criteria Of The Eastern Cooperative Oncology Group. American Journal of Clinical Oncolgy. 1982; 5: 649–655.
  7. 7. Takagi Masamichi, Yamazi Tomohisa, Yano HEiichi. Placement of an expandable metallic stent(Ultraflex) for tracheabronchial stenosis in relapsing polychondritis. Journal of Japanese Respiratory Society.2006;44:997–1001.
  8. 8. Jordhoy MS, Fayers P, Loge JH, Saltnes T, Ahlner-Elmqvist M, Kaasa S. Quality of life in advanced cancer patients: the impact of sociodemographic and medical characteristics. British Journal of cancer.2001;85(10): 1478–85. pmid:11720432
  9. 9. Wilson G E, Walshaw M J, Hind C R K. Treatment of large airway obstruction in lung cancer using expandable metal stents inserted under direct vision via the fibreoptic bronchoscope.Thorax.1996;51:248–52. pmid:8779125
  10. 10. Ma Gang, Wang Dao-Fang, Quan-Quan , Lou Ning, Zhu Zi-Wei, Fu Jian-Hua et al. Tracheal stent implantation for the treatment of tumor-induced acute airway stenosis. Chinese Journal of Cancer. 2008; 27:153–6.
  11. 11. Puchalski Jonathan. Tracheal and Bronchial Stenosis: Etiologies, Bronchoscopic Interventions and Outcomes. Pakistan Journal of Chest Medicine.2012;18: 38–46.
  12. 12. Prigerson Holly G.,Bao Yuhua, Shah Manish A. Chemotherapy Use, Performance Status and Quality of Life at the End of Life. JAMA Oncology. 2015; 1(6): 778–84. pmid:26203912
  13. 13. Davis N., Madden B.P.. Airway management of patients with tracheobronchial stents. British Journal of Anaesthesia. 2006;96:132–5. pmid:16257995
  14. 14. Harvella Georgia, George Jeremy. Interventional bronchoscopy in the management of thoracic malignancy. Breathe.2015;11:203–11.
  15. 15. Agrafiotis Michalis, Siempos Ilias I., Falagas Matthew E., Infections Related to Airway Stenting: A Systematic Review. Interventional Pulmonology. 2009;78:69–74.
  16. 16. Herth F.J.F., Peter S., Baty F., Eberhardt R., Leuppi J D, Chhajed P N. Combined airway and oesophageal stenting in malignant airway-oesophageal fistulas: a prospective study. European Respiratory Journal.2010;36:1370–4. pmid:20525708
  17. 17. Paganin Fabrice, Schouler Laurent, Cuissard Laurent, Noel Jean Baptiste, Becquart Jean-Philippe, Besnard Mathieu et al. Airway and Esophageal Stenting in Patients with Advanced Esophageal Cancer and Pulmonary Involvement. PLOS ONE.2008;3:1–7.
  18. 18. Puchalski Jonathan, Musani Ali. Tracheobronchial Stenosis: Causes and Advances in Management. Clin Chest Med.2013;34:557–67. pmid:23993823
  19. 19. Saji Hisashi, Furukawa Kinya, Tsutsui Hidemitsu Tsuboi Masahiro, Ichinose Shuji, Usuda Jitsuo et al.Outcomes of airway stenting for advanced lung cancer with central airway obstruction. Interactive CardioVascular and Thoracic Surger. 2010;11:425–28.
  20. 20. McGrath Emmet E., Warriner David, Anderson Paul. The insertion of self expanding metal stents with flexible bronchoscopy under sedation for malignant tracheobronchial stenosis. Archivos de Bronconeumologia. 2012;48:43–8. pmid:22137422
  21. 21. Zakaluzny SA, Lane JD, Mair EA. Complications of tracheabronchial airway stents. Otolaryngol Head Neck Surgery. 2003;128(4):478–88.
  22. 22. Hong Yoonki, Jo Kyung-Wook, Lyu Jiwon, Choi Chang Min. Use of venovenous extractoreal membrane oxygenateon in central airway obstruction to facilitate interventions leading to definitive airway securety. Journal of Critical Care. 2013;28:69–74.
  23. 23. Eon Ji, Jung Sung-Ho, Ma Dac Sung,. Experiences of Tracheal Procedure Assisted by Extracorporeal Membrane Oxgenator. Korean Journal of Thoracic Cardiovascular Surgery. 2013;46: 80–3. pmid:23423782
  24. 24. Conacher I.D.. Anaesthesia and tracheobronchial stenting for central airway obstruction in adults. British Journal Anaesthesia. 2003;90:367–74