Impact of the type of initial intervention on the outcomes of lung volume reduction for emphysema: a propensity matched study
Introduction
Chronic obstructive pulmonary disease (COPD) is projected to induce an important sector of strain in healthcare systems as it is connected with high number of exacerbations, needs for medical treatment, admissions to hospital and deaths (1,2).
Lung volume reduction for emphysema [lung volume reduction surgery (LVRS) or endobronchial valves (EBVs)] can improve survival when compared to medical treatment in appropriately selected patients (3,4).
These interventional modalities are offered to patients after discussion at a dedicated emphysema multidisciplinary team (MDT), as recommended by the National Institute of Clinical Excellence (NICE) guidelines (5,6).
The decision to select one modality over the other is not always straight forward, with many cases being suitable for both. The difficulty in reaching a decision with regards to which modality to offer as initial treatment i.e., EBVs or LVRS in those cases, is augmented by the lack of studies comparing the outcomes of these 2 modalities.
The objective of the present study was to compare the outcomes of LVRS versus EBVs performed in patients who could have both offered as an initial treatment. We present the following article in accordance with the STROBE reporting checklist (available at https://atm.amegroups.com/article/view/10.21037/atm-22-2429/rc).
Methods
After retrospectively reviewing 153 emphysema patients treated with an intervention between 2012–2017 at our institute, 111 were identified as potential candidates for both EBVs or LVRS to be offered as the initial intervention (the rest 42 were shifted towards one intervention because of incomplete fissures on imaging or patient fitness etc., and hence were excluded from the study, Figure 1). This decision was either documented in the notes after discussion at the emphysema MDT or was made by a group of physicians with a special interest in emphysema interventions (prior to the establishment of the MDT) with patients having unobstructed and equal access to these modalities. All interventions were performed by board certified surgeons/respiratory physicians with a special interest in emphysema.
None of the patients included in this study was referred for lung transplantation following the LVR intervention and during the study period.
All decisions were based on NICE guidelines and on the findings of the National Emphysema Trial (NET) trial (Table 1) (3,6-8) Patients who fulfilled the criteria for LVR intervention and had developed fissures [proved on thin slice computed tomography (CT) scan and the Strat-X analysis] could also be eligible for EBVs apart from LVRS (6). In the cases where both modalities could be offered as initial potential treatments (and are included in this study), the final decision about what type of intervention to offer was made after discussing the risks and the benefits with the patients.
Table 1
| Age 40–80 years |
| MRC Dyspnea score ≥4 |
| CAT score ≥20 |
| Heterogenous, apical emphysema |
| Completion of fissures on 1 mm CT and favorable Strat-X (for EBV mainly) |
| FEV1 between 20–40% (different levels are considered per patient) |
| RV above 200% (different levels are considered per patient) |
| Smoking cessation for at least 6 months |
| At least one course of rehabilitation completed |
| BMI >18 (for LVRS mainly) |
| Performance score (ECOG) 0–3 |
| ECG, ECHO acceptable |
| Co-morbidities or other issues considered per patient |
LVR, lung volume reduction; NICE, National Institute of Clinical Excellence; NET, National Emphysema Trial; MRC, Medical Research College; CAT, COPD Assessment Test; CT, computed tomography, Strat-X platform Pulmonics®; EBV, endobronchial valve; FEV1, forced expiratory volume in 1st second; RV, residual volume; BMI, body mass index; LVRS, lung volume reduction surgery; ECOG, Eastern Cooperative Oncology Group; ECG, electrocardiogram; ECHO, echocardiograph.
Data
All data collected included; age and gender, pre-interventional pulmonary function [forced expiratory volume in 1 sec (FEV1), diffusional lung capacity for carbon monoxide (DLCO), total lung capacity (TLC), residual volume (RV)], comorbidities (not COPD/emphysema), exercise tolerance (as noted during a 6-minute walking test-6MWT or as documented by the physician in the notes) and performance status [Eastern Cooperative Oncology Group (ECOG classification)]. Also, the quantity and whether EBV or LVRS was performed and re-interventions (also for complications) were noted. Additionally, post-interventional morbidity, quality of life/breathing change post-intervention as subjectively reported by the patients at 3–6 months appointment after their interventions (captured as same, better or worse) and overall quality of life change by determining a COPD Assessment Test (CAT) score during these follow up appointments. The total length of stay (LOS) i.e., the LOS of all in-hospital stays (total number of days of all admissions) was captured for both modalities as well as the 30-day mortality (mortality documented throughout all in-hospital stays for all interventions when more than one) and survivorship (deaths up to the end of the study).
All data were collected from our on-line Patient Pathway Manager Plus domain (PPM+), the dedicated emphysema intervention database of the Thoracic Surgery Department and the patient case notes wherever appropriate.
For LVRS group, a re-intervention mainly involved re-operation for morbidity i.e., bleeding, prolonged air leak etc. as intervention on the contralateral side was perceived as a separate case. For EBV group, any intervention on the valves after their implementation i.e., repositioning, changing or removed. Also, for both modalities insertion/re-insertion of chest drain was perceived as a re-intervention. ChartisTM catheter assessment for collateral ventilation alone was not considered as a separate intervention.
Morbidity was captured as respiratory (chest infection but not exacerbation of COPD, respiratory failure), cardiac (arrhythmia, myocardial infarction, cardiovascular failure), surgical (surgical emphysema, pneumothorax, wound infection, prolonged air leak, empyema) and other complications (for example renal, stroke etc.).
Follow-up
Follow-up documentation was noted up to January 2020. The median follow-up was 32 months (range, 0–84).
Description of interventions
LVRS was performed via biportal or 3-port video-assisted thoracic surgery (VATS) with buttressed bovine pericardium (PeristripsTM) staplers. At the end 1 or 2 drains were variably left into the chest. Only lung parenchyma shaving but no anatomical lung resections i.e., lobectomies were performed.
EBV insertion was conducted under general anesthesia and the use of rigid bronchoscope via which a flexible bronchoscope with adequate size working channel was used to deliver the measurement catheter with the valve (Zephyr®, PulmonX Corporation, CA, USA). This event happened after performance of a ChartisTM assessment i.e., absence of collateral ventilation.
All procedures were unilateral i.e., no bilateral procedures simultaneously were performed. During the period of the study our institute offered intervention only in patients with heterogenous and apical distribution of emphysema. Contralateral procedures for disease progression were perceived as separate treatment.
All patients recovered on a ward setting which includes a high dependency unit operated by specialist personnel apart from our team. Standard protocols of treatment (i.e., analgesia, anticoagulation and thromboprophylaxis, physiotherapy etc.) were utilized for all patients according to the type of intervention (EBV or LVRS).
Study design
In order to exclude biased patient selection for treatment (Table 2) matching was performed for age, gender, BMI, pulmonary function, performance status, and exercise tolerance with propensity scores occurring from binary logistic regression and using the “nearest neighbor” technique—matching tolerance of 0.2 and matching in a 1:1 basis. Forty-four (44) matched pairs were yielded and were used for analysis. Because of the limited number of patients, the scoring was conducted based on these limited values excluding other potential ones.
Table 2
| Variables | LVRS, n=48 | EBV, n=51 | P value |
|---|---|---|---|
| Age in years (mean ± SD) | 61.5±9.7 | 61.7±10.3 | 0.908* |
| Male gender (n, %) | 29 (60.4) | 33 (64.7) | 0.041** |
| BMI (kg/m2) (mean ± SD) | 22.86±9.3 | 24.4±8.7 | 0.039* |
| Performance status, median [lowest–highest] | 2 [1–3] | 2 [1–3] | 0.150# |
| Pulmonary function (mean ± SD) | |||
| FEV1 | 39.8±16.1 | 32.5±9.3 | 0.004* |
| DLCO | 37.4±11.2 | 35.3±11.4 | 0.347* |
| TLC | 122.9±20.8 | 129.5±20.6 | 0.031* |
| RV | 184.4±53.5 | 213.9±48.9 | 0.013* |
| Exercise tolerance in meters (mean ± SD) | 193.3±26.1 | 157.3±23.8 | 0.032* |
*, Student’s t-test; **, Chi-square test; #, Mann-Whitney Test. LVRS, lung volume reduction surgery; EBV, endobronchial valve; SD, standard deviation; BMI, body mass index; FEV1, forced expiratory volume in 1st second; DLCO, diffusional lung for carbon dioxide; TLC, total lung capacity; RV, residual volume.
The primary endpoint was the survival probability between the 2 modalities. Secondary endpoints were; the performance of another intervention (1st re-intervention) after initial intervention, the total number of re-interventions and hazard of re-interventions by time, and other outcomes such as the quality of life change reported by patients and the overall quality of life calculated via CAT scores on follow-up, the LOS, the morbidity and in-hospital/30-day mortality.
The study was conducted in accordance with the Declaration of Helsinki (as revised in 2013). The study was discussed with the Research and Development department of The Leeds Teaching Hospitals NHS Trust and a NHS Research Ethics Committee was not considered appropriate. The R&D department waived the need for ethical approval and consent which was verified by the clinical governance meeting of the department.
Analysis
The data were captured by a data manager who was unaware of the outcomes of the study and therefore data accumulation was blinded. The analysis was done by 2 authors of the study separately therefore data analysis was not blinded. Both are not members of the MDT.
The IBM SPSS Statistics for Macintosh, Version 22.0. Armonk, New York: IBM Corp was used for analysis. Figures 2,3 were produced with R version 3.6.2.
All numerical data were presented as mean ± standard deviation (SD). Skewed data were presented as median (lower value – higher value). Categorical data were presented as number of observations and percentages.
Statistically significant level was accepted at P<0.05.
In order to capture the hazard of all re-interventions per modality by time a Nelson-Aalen analysis was performed.
Missing data were handled by conducting complete case analysis with decision to exclude appropriate cases.
Kaplan-Meier’s survival curves and long-rank were used to investigate long survival. The last date investigated was the 18th January 2020.
Results
In the initial unmatched population, the gender, the pulmonary function tests (FEV1, TLC, RV), the BMI and the exercise tolerance were different between patients treated with EBVs and patients treated with LVRS (Table 2).
After complete case analysis, 12 cases were found to have missing values from essential data (from the 111 eligible patients) and therefore were not included in the propensity matching process.
After propensity matching (pool of 99 patients, Figure 1), the 2 groups were consisted of 44 pairs of patients with similar characteristics (Table 3) and comorbidities (Table 4).
Table 3
| Variables | LVRS, n=44 | EBV, n=44 | P value |
|---|---|---|---|
| Age in years (mean ± SD) | 60.98±9.4 | 62.74±9.6 | 0.363* |
| Male gender (n, %) | 29 (65.9) | 26 (59.1) | 0.436** |
| BMI (kg/m2) (mean ± SD) | 28.25±11.1 | 25.85±10.3 | 0.388* |
| Performance status, median [lowest–highest] | 2 [1–3] | 2 [1–3] | 0.150# |
| Performance status analytically (n, %) | 0.827** | ||
| 1 | 8 (18.2) | 7 (15.9) | |
| 2 | 28 (63.6) | 31 (70.5) | |
| 3 | 8 (18.2) | 6 (13.6) | |
| Pulmonary function (mean ± SD) | |||
| FEV1 | 36.8±14.2 | 36.7±11.3 | 0.970* |
| DLCO | 37.31±11.5 | 36.82±11.32 | 0.844* |
| TLC | 125.11±20.97 | 121.64±19.4 | 0.537* |
| RV | 192.35±55.4 | 196.78±45.97 | 0.717* |
| Exercise tolerance in meters (mean ± SD) | 189.94±23.9 | 184.17±29.3 | 0.504* |
Standard differences calculated using the mean or proportions. *, Student’s t-test; **, Chi-square test; #, Mann-Whitney Test. LVRS, lung volume reduction surgery; EBV, endobronchial valve; SD, standard deviation; BMI, body mass index; FEV1, forced expiratory volume in 1st second; DLCO, diffusional lung for carbon dioxide; TLC, total lung capacity; RV, residual volume.
Table 4
| Variables | LVRS, n=44 | EBV, n=44 | P value |
|---|---|---|---|
| Cardiovascular (n, %) | 16 (36.4) | 16 (36.4) | 0.899‡ |
| CAD/Angina/MI | 10 | 11 | |
| HT | 4 | 2 | |
| PVD | 1 | 1 | |
| Arrhythmia/AF | 1 | 2 | |
| Respiratory other than COPD/emphysema (n, %) | 4 (9.1) | 5 (11.4) | 0.911‡ |
| Bronchiectasis/Pneumonia | 1 | 1 | |
| Cannabis induced lung pathology | 1 | 2 | |
| Asthma | 2 | 2 | |
| Previous cancer (non-lung) (n, %) | 6 (13.6) | 2 (4.5) | 0.667‡ |
| Musculoskeletal/Rheumatologic (n, %) | 5 (11.4) | 6 (13.6) | 0.997** |
| Other (n, %) | 5 (11.4) | 6 (13.6) | 0.997** |
| No other co-morbidities (n, %) | 19 (43.2) | 18 (40.1) | 0.866** |
**, Chi-square test; ‡, Fischer’s Exact test. LVRS, lung volume reduction surgery; EBV, endobronchial valve; CAD, coronary artery disease; HT, hypertension; PVD, peripheral vascular disease; AF, atrial fibrillation; COPD, choric obstructive pulmonary disease.
The mean age of the 88 matched patients included in the study was 61.91±9.48 years and 55 (62.5%) were males.
Eleven deaths were captured in the LVRS group and 8 in the EBV group (P=0.437). Excluding the 30-day mortality, patients died because of their disease progression in the form of respiratory issues. However, survival was similar between the 2 groups (log-rank 0.002, P=0.350, CI: 58.832–72.730, Figure 2).
The total number of re-interventions was higher in the EBV group and more patients from this group had at least 1 re-intervention necessitated throughout the study (Table 5). However, the hazard of re-interventions as repeated events by time was not shown to be different between the 2 modalities (P=0.766, Figure 3).
Table 5
| Variables | LVRS, n=44 | EBV, n=44 | P value |
|---|---|---|---|
| LOS in days, median [lower–higher] | 10 [0–28] | 6 [1–32] | 0.006# |
| Morbidity (n, %) | 11 (25.0) | 9 (20.5) | 0.611** |
| Total number of interventions, median [lower–higher] | 1 [1–4] | 2 [1–6] | 0.005‡ |
| At least 1 re-intervention (n, %) | 9 (20.5) | 24 (54.5) | 0.002** |
| MDT involvement in decision (n, %) | 26 (59.1) | 14 (31.8) | 0.010** |
| CAT Improvement (mean ± SD) | 7.89±1.2 | 3.67±1.9 | 0.034† |
| Same or better overall quality of life and breathing ability after intervention (patient report) (n, %) | 38 (86.4) | 31 (70.5) | 0.002** |
| 30-day mortality (n, %) | 2 (4.5) | 1 (2.3) | 0.557‡ |
**, Chi-square test; #, Mann-Whitney test; ‡, Fischer’s Exact test; †, Paired t-test. LVRS, lung volume reduction surgery; EBV, endobronchial valve; LOS, length of stay; SD, standard deviation; MDT, multidisciplinary team; CAT, COPD assessment test.
Twelve patients (27.3%) underwent initial re-intervention with re-positioning of their valves because the volume reduction effect was lost (in 10 of them EBVs had to be repositioned for more than 1 times). In 6 cases (13.6%) the valves were coughed out by the patient (and were repositioned) and in 2 (4.5%) the valves had to be removed because of bleeding post insertion (these patients finally underwent LVRS). The median number of valves inserted was 3 [2–6]. In 4 cases a chest drain was necessitated to be inserted for pneumothorax (mentioned also below).
In the LVRS group, re-intervention included surgery for morbidity (as described in the methods section). More specifically, 3 patients (6.8%) had to be reoperated for significant postoperative air leak and another 3 (6.8%) for empyema. In 2 (4.5%) patients, redo LVRS was attempted. In 1 case (2.3%) the reason of reoperation/re-intervention was not documented. The LOS was longer in the LVRS group (Table 5).
Overall morbidity was similar in the 2 groups (Table 5). Morbidity in the EBV group regarded mainly pneumothorax development after implantation in 7 patients (15.9% with a chest drain inserted in 4 of them i.e., re-intervention for pneumothorax) and respiratory failure with pneumonia in the rest 2 patients (4.5%). In the LVRS group, morbidity mainly regarded prolonged air leak in 6 cases (13.6%, 2 of which were discharged home with a drain in situ and 2 required a blood patch) and respiratory failure with/without pneumonia in 3 (6.8%). A patient developed a stroke and another one sustained myocardial infarction (2.3% respectively).
Within 6–12 months from the intervention, the CAT score was improved in both groups (Table 5) but the one calculated in the LVRS group (from 26.33 preoperatively to 18.44 postoperatively) was significantly more intense than the CAT difference calculated in the EBV group (from 25.67 preoperatively to 22 postoperatively, P=0.034). More patients reported the same or improved quality of life and breathing ability after intervention from the LVRS group than from the EBV group (Table 5).
The in-hospital and 30-day mortality were similar in the 2 groups and regarded 1 empyema patient after LVRS with multi-organ failure, 1 patient with respiratory failure after LVRS and 1 patient who developed respiratory failure after EBV insertion (Table 4).
Conclusions
The 2 modalities showed similar survival probability. Patients who were offered EBV insertion as the initial treatment had more re-interventions performed. Apart from LOS, which was longer in the LVRS group, the morbidity as well as the in-hospital/30-day mortality were similar between the 2 groups. Improvement of their overall health was better after LVRS as subjectively reported by the patients and objectively measured with CAT scores.
In this study, the number of re-interventions was secondarily investigated as the treated patients had already reached the ceiling of improvement with medical treatment, and hence a small number of re-interventions would be ideally better for their post-intervention life. The difference in the number of re-interventions could partially be attributed to the fact that the LVRS is an irreversible procedure whilst EBVs can be undone i.e., removed or repositioned. Although less re-interventions were necessitated for patients receiving LVRS as the initial intervention, re-intervention risk by time was not different between the 2 modalities and therefore this outcome needs further investigation.
Another outcome was the impact on the overall health of the patients. More patients in the LVRS group reported improvement of this including their breathing ability. Additionally, their CAT score was more effectively reduced. CAT score has been shown to correlate with post-interventional overall health status (9,10).
Morbidity was similar in the 2 groups. Its treatment necessitated re-interventions in both groups and in many occasions a return to theatre with general anaesthesia was required. Additionally, pneumothorax was an important type of morbidity for the EBV group in this study and this agreed with literature (11).
Likewise, the LOS was lengthier in the LVRS group. This finding implies that LVRS intervention recovery necessitates prolonged in-hospital stay which was not the case for EBVs although the more re-interventions needed.
LVRS, despite evolving over the years from an open sternotomy to VATS or Robotic techniques offering less trauma, quicker recovery and lower morbidity and mortality (12-14), it still involves a surgical procedure. EBVs on the other hand, are performed without invasive surgery and in some in some cases without general anaesthesia (15). Consequently, LVRS has notoriously been perceived as more “dangerous”, making EBVs a safer choice (16,17). Results from this study show that this notion was not verified.
The benefit of EBV insertion on respiratory function, improvement of exercise tolerance and quality of life without increased exacerbations and mortality, has extensively been proven in the literature (18-20). Similarly, the surgical lung volume intervention can achieve survival benefit when compared with patients who have only received medical treatment (3,13). The two interventional modalities, therefore, have been extensively compared with the optimized medical treatment but not amongst them.
Clear guidelines as to when or to whom to offer one or the other modality do not exist. Practice up to recent years considered that LVRS is more dangerous and therefore should not be offered to compromised patients (17), in whom EBVs would seem to be a better alternative. This study shows that the 2 modalities present similar morbidity and mortality and therefore both could be safely offered.
Even outside the MDT (which can be the case in many countries/departments, private sector etc.), patients received treatment based on NICE guidelines and NET findings. Chartis assessment ensured that EBV insertion would work. Although it was previously shown that the MDT would shift cases towards LVRS, in this study cases could have both modalities offered and therefore this previous finding was not perceived as relevant while setting up the present study.
This study has several limitations. It is a retrospective, small and single institute study, investigating a short period of study time without long-term data regarding breathing improvement. Another limitation was that lung function tests (LFTs) or 6MWT post intervention were requested variably by physicians and MDT and therefore a meaningful analysis regarding breathing improvement post-intervention could not be performed, hence objective measurement of the improvement of the breathing ability was not performed. Moreover, patients were included in the study based on what was documented and therefore it was not possible to check if decisions for both modalities were correctly taken. Finally, some important variables could have been included in the analysis of the propensity matching but that would limit substantially the included in the study cases making a reasonable analysis unfeasible. Based on the above and on the fact that this was not a blinded study, bias could be involved in the results and therefore results should be considered with caution.
Although results from this study do not allow the formulation of an “algorithm” as to what type of intervention to be offered first, it provides an insight of the pros and cons of each modality and attempts, with limitations, the first comparison, to our knowledge, between these two modalities. The results of the randomized trial CELEB study, which is designed to compare EBV vs. LVRS in patients who could offered both interventions, are expected to come out soon (21).
In conclusion, this study shows that both modalities are safe and therefore can be considered as an initial treatment to emphysema patients. EBVs showed shorter LOS whilst LVRS necessitated less re-interventions but led to better overall health improvement than EBVs. We hope that our small study will prove to be a springboard for future efforts to rectify the current dearth of data, of such an important aspect of Lung Volume Reduction.
Acknowledgments
Parts of this study were presented at the Society For Cardiothoracic Surgery in Great Britain and Ireland, March 2018, Glasgow and at the European Association for Cardiothoracic Surgery annual meeting in Milan, October 2018.
Funding: None.
Footnote
Reporting Checklist: The authors have completed the STROBE checklist. Available at https://atm.amegroups.com/article/view/10.21037/atm-22-2429/rc
Data Sharing Statement: Available at https://atm.amegroups.com/article/view/10.21037/atm-22-2429/dss
Peer Review File: Available at https://atm.amegroups.com/article/view/10.21037/atm-22-2429/prf
Conflicts of Interest: All authors have completed the ICMJE uniform disclosure form (available at https://atm.amegroups.com/article/view/10.21037/atm-22-2429/coif). VK serves as an unpaid editorial board member of Annals of Translational Medicine from December 2021 to November 2023. The other authors have no conflicts of interest to declare.
Ethical Statement: The authors are accountable for all aspects of the work in ensuring that questions related to the accuracy or integrity of any part of the work are appropriately investigated and resolved. The study was conducted in accordance with the Declaration of Helsinki (as revised in 2013). The study was discussed with the Research and Development department of The Leeds Teaching Hospitals NHS Trust and a NHS Research Ethics Committee was not considered appropriate. The R&D department waived the need for ethical approval and consent which was verified by the clinical governance meeting of the department.
Open Access Statement: This is an Open Access article distributed in accordance with the Creative Commons Attribution-NonCommercial-NoDerivs 4.0 International License (CC BY-NC-ND 4.0), which permits the non-commercial replication and distribution of the article with the strict proviso that no changes or edits are made and the original work is properly cited (including links to both the formal publication through the relevant DOI and the license). See: https://creativecommons.org/licenses/by-nc-nd/4.0/.
References
- Lozano R, Naghavi M, Foreman K, et al. Global and regional mortality from 235 causes of death for 20 age groups in 1990 and 2010: a systematic analysis for the Global Burden of Disease Study 2010. Lancet 2012;380:2095-128. [Crossref] [PubMed]
- Mathers CD, Loncar D. Projections of global mortality and burden of disease from 2002 to 2030. PLoS Med 2006;3:e442. [Crossref] [PubMed]
- Fishman A, Martinez F, Naunheim K, et al. A randomized trial comparing lung-volume-reduction surgery with medical therapy for severe emphysema. N Engl J Med 2003;348:2059-73. [Crossref] [PubMed]
- Hartman JE, Welling JBA, Klooster K, et al. Survival in COPD patients treated with bronchoscopic lung volume reduction. Respir Med 2022;196:106825. [Crossref] [PubMed]
- Rathinam S, Oey I, Steiner M, et al. The role of the emphysema multidisciplinary team in a successful lung volume reduction surgery programme†. Eur J Cardiothorac Surg 2014;46:1021-6. [Crossref] [PubMed]
- Kouritas V, Milton R, Kefaloyannis E, et al. The Impact of a Newly Established Multidisciplinary Team on the Interventional Treatment of Patients With Emphysema. Clin Med Insights Circ Respir Pulm Med 2019;13:1179548419852063. [Crossref] [PubMed]
- National Institute for Clinical Excellence. Chronic obstructive pulmonary disease in over 16s: diagnosis and management. Available online: https://www.nice.org.uk/guidance/ng115
- BTS NICE. Chronic Obstructive Pulmonary Disease Quality Standards. London, National Institute for Health and Care Excellence, 2011.
- Karloh M, Fleig Mayer A, Maurici R, et al. The COPD Assessment Test: What Do We Know So Far?: A Systematic Review and Meta-Analysis About Clinical Outcomes Prediction and Classification of Patients Into GOLD Stages. Chest 2016;149:413-25. [Crossref] [PubMed]
- Wienker J, Karpf-Wissel R, Funke F, et al. Predictive value of Chartis measurement for lung function improvements in bronchoscopic lung volume reduction. Ther Adv Respir Dis 2020;14:1753466620932507. [Crossref] [PubMed]
- Labarca G, Uribe JP, Pacheco C, et al. Bronchoscopic Lung Volume Reduction with Endobronchial Zephyr Valves for Severe Emphysema: A Systematic Review and Meta-Analysis. Respiration 2019;98:268-78. [Crossref] [PubMed]
- Huang W, Wang WR, Deng B, et al. Several clinical interests regarding lung volume reduction surgery for severe emphysema: meta-analysis and systematic review of randomized controlled trials. J Cardiothorac Surg 2011;6:148. [Crossref] [PubMed]
- Criner GJ, Cordova F, Sternberg AL, et al. The National Emphysema Treatment Trial (NETT) Part II: Lessons learned about lung volume reduction surgery. Am J Respir Crit Care Med 2011;184:881-93. [Crossref] [PubMed]
- McKenna RJ Jr, Benditt JO, DeCamp M, et al. Safety and efficacy of median sternotomy versus video-assisted thoracic surgery for lung volume reduction surgery. J Thorac Cardiovasc Surg 2004;127:1350-60. [Crossref] [PubMed]
- Herzog D, Thomsen C, Poellinger A, et al. Outcomes of Endobronchial Valve Treatment Based on the Precise Criteria of an Endobronchial Catheter for Detection of Collateral Ventilation under Spontaneous Breathing. Respiration 2016;91:69-78. [Crossref] [PubMed]
- McNulty W, Jordan S, Hopkinson NS. Attitudes and access to lung volume reduction surgery for COPD: a survey by the British Thoracic Society. BMJ Open Respir Res 2014;1:e000023. [Crossref] [PubMed]
- Zoumot Z, Jordan S, Hopkinson NS. Emphysema: time to say farewell to therapeutic nihilism. Thorax 2014;69:973-5. [Crossref] [PubMed]
- Davey C, Zoumot Z, Jordan S, et al. Bronchoscopic lung volume reduction with endobronchial valves for patients with heterogeneous emphysema and intact interlobar fissures (the BeLieVeR-HIFi study): a randomised controlled trial. Lancet 2015;386:1066-73. [Crossref] [PubMed]
- Kemp SV, Slebos DJ, Kirk A, et al. A Multicenter Randomized Controlled Trial of Zephyr Endobronchial Valve Treatment in Heterogeneous Emphysema (TRANSFORM). Am J Respir Crit Care Med 2017;196:1535-43. [Crossref] [PubMed]
- Criner GJ, Sue R, Wright S, et al. A Multicenter Randomized Controlled Trial of Zephyr Endobronchial Valve Treatment in Heterogeneous Emphysema (LIBERATE). Am J Respir Crit Care Med 2018;198:1151-64. [Crossref] [PubMed]
- Buttery S, Kemp SV, Shah PL, et al. CELEB trial: Comparative Effectiveness of Lung volume reduction surgery for Emphysema and Bronchoscopic lung volume reduction with valve placement: a protocol for a randomised controlled trial. BMJ Open 2018;8:e021368. [Crossref] [PubMed]
