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PULMONARY AIR LEAKS 

​Proper lung functioning depends on the separation between the air-containing parts of the lung and the small vacuum-containing space around the lung called the pleural space. When air leaks into the pleural space, the lung is unable to inflate, resulting in hypoventilation and hypoxemia; this condition is known as a pneumothorax. A pneumothorax can result from trauma, high airway pressures induced during mechanical ventilation, lung surgery, and rupture of lung blebs or bullae, which may be congenital or a result of chronic obstructive pulmonary disease (COPD).

EMPHYSEMA

Emphysema, a form of COPD, is a progressive, debilitating disease characterized by irreversible destruction of alveolar tissue. This destruction results in reduced elastic recoil, progressive hyperinflation and gas trapping with individuals experiencing chronic dyspnea, limited exercise tolerance, and poor health-related quality of life. In emphysematous COPD, diseased portions of the lung ventilate poorly, cause air trapping, and hyperinflate, compressing relatively normal lung tissue. The patterns and degree of emphysema heterogeneity (i.e., the extent and distribution of air space enlargements) can be measured using computed tomography (CT) density as an indicator for tissue destruction. The most diseased portions of lung can then potentially be targeted for lung volume reduction procedures. In homogeneous emphysema, there is minor or no regional difference in disease within or between lobes of the lung.

The Global Initiative for Chronic Obstructive Lung Disease, or GOLD, system is commonly used to categorize individuals with emphysema according to severity. Stages of airflow limitation are based on the forced expiratory volume in 1 second (FEV₁; or the amount of air a person can force out in 1 second after taking a deep breath). Individuals with an FEV₁ of less than 50% of their predicted value are considered to have severe airflow limitation. Individuals are also grouped in the GOLD system according to categories of risk of having an exacerbation. These groups are based on number and type of exacerbations per year and self-reported symptoms such as breathlessness.

BRONCHIAL VALVES

Bronchial valves are synthetic devices deployed with bronchoscopy into ventilatory airways of the lung to control airflow. During inhalation, the valve is closed, preventing air flow into the diseased area of the lung. The valve opens during exhalation to allow air to escape from the diseased area of the lung. They have been investigated for use in individuals who have prolonged bronchopleural air leaks and in individuals with lobar hyperinflation from severe or advanced emphysema.

When used to treat persistent air leaks from the lung into the pleural space, the bronchial valve theoretically permits less air flow across the diseased portion of the lung during inhalation, aiding in air leak closure. The valve may be placed, and subsequently removed, by bronchoscopy.

The use of bronchial valves to treat emphysema is based on the improvement observed in individuals who have undergone lung volume reduction surgery. Lung volume reduction surgery involves excision of peripheral emphysematous lung tissue, generally from the upper lobes. The precise mechanism of clinical improvement for individuals undergoing lung volume reduction has not been firmly established. However, it is believed that elastic recoil and diaphragmatic function are improved by reducing the volume of the diseased lung. Currently, and at the time the clinical trials were designed, very few lung volume reduction procedures were performed. The procedure is designed to relieve dyspnea and improve functional lung capacity and quality of life; it is not curative. Medical management remains the most common treatment for a majority of individuals with severe emphysema.

In early trials of bronchial valves for treatment of emphysema, absence of collateral ventilation (pathways that bypass the normal bronchial airways) was associated with better outcomes, presumably because individuals with collateral ventilation did not develop lobar atelectasis (collapse). In subsequent trials, individuals were selected for absence of collateral ventilation, and it is current practice for individuals to be assessed for the presence of collateral ventilation prior to undergoing the procedure. Collateral ventilation is measured by the Chartis System, which requires bronchoscopy, or as a surrogate, CT scanning to assess the completeness of fissures. After 45 days postprocedure, residual volume can provide information on whether lung volume reduction has been achieved successfully.​

Two major and different types of valves—endobronchial valves (Zephyr®, Pulmonx Corp., Redwood City, CA, USA) and intrabronchial valves (IBV, Spiration®, Olympus, Tokyo, Japan)—are available, and they differ in shape but have a similar mechanism of action. The two valve systems differ in the mechanism by which the one-way valve is created: the Zephyr, a duckbill shape, and the Spiration, an umbrella shape. The choice between one of the two types is influenced more by the bronchial anatomy rather than by different outcomes after valve placement. Although no comparative trial has been published, the effect of both types of valves seems to be similar. (Additionally, In October 2008, the Spiration® IBV Valve System was approved by the US Food and Drug Administration [FDA] through the humanitarian device exemption [HDE] [H060002] process for use in controlling prolonged air leaks of the lung or significant air leaks that are likely to become prolonged air leaks following lobectomy, segmentectomy, or lung volume reduction surgery). In rare instances, certain medical devices intended to be used for humanitarian purposes are evaluated by the FDA through the HDE process. The FDA’s humanitarian use device (HUD) designation permits the use of certain medical devices when there is no comparable device available to treat or diagnose a disease or condition affecting fewer than 4000 individuals annually. Because clinical investigation demonstrating the device's efficacy is not feasible (given the low prevalence of the disease in the population), an HDE grants manufacturers an exemption to the usual premarket approval process and allows marketing of the device only for the FDA-labeled HDE indication(s). Under FDA requirements, an HUD may only be used after institutional review board (IRB) approval has been obtained for the use of the device in accordance with the FDA-labeled indication(s) under the HDE.

PEER-REVIEWED LITERATURE

Zephyr Valve

Criner et al. (2018) conducted the pivotal trial evaluating the safety and effectiveness of the Zephyr valve in individuals with heterogeneous​ emphysema with little to no collateral ventilation in the target lobe. A total of 190 individuals were randomly assigned (2:1; Zephyr or standard of care) in this intent-to-treat analysis. The primary outcome was the difference between groups in percentage of individuals with a 15% or greater improvement in forced expiratory volume in one second (FEV₁) at 12 months. Additional outcomes included absolute change in FEV₁, St. George’s Respiratory Questionnaire (SGRQ), and 6-minute walking distance (6MWD), among others. There was a 31% difference between the Zephyr and standard of care groups in the percentage of individuals whose FEV₁ improved by 15% or more (47.7% and 16.8%, respectively; P<0.001). All additional secondary endpoints were also statistically significant, favoring Zephyr compared to standard of care. There were significantly more serious adverse events at day 45 in the Zephyr group than the standard of care group, primarily driven by an increase in pneumothorax. 

Dransfield et al. performed a post hoc analysis of patient-reported outcomes (PROs), including multidimensional measures of dyspnea, activity, and quality of life, in the Lung Function Improvement after Bronchoscopic Lung Volume Reduction with Pulmonx Endobronchial Valves used in Treatment of Emphysema (LIBERATE) study in 2020. Changes in PROs at 12 months in the two groups were compared: dyspnea with the Transitional Dyspnea Index (TDI), focal score; the Chronic Obstructive Pulmonary Disease Assessment Test (CAT; breathlessness on hill/stairs); Borg; the EXAcerbations of Chronic pulmonary disease Tool-PRO, dyspnea domain; activity with the TDI, magnitude of task/effort/functional impairment, CAT (limited activities), and the SGRQ, activity domain; and psychosocial status with the SGRQ, impacts domain, and CAT (confidence and energy). At 12 months, individuals using the Zephyr valve achieved statistically significant and clinically meaningful improvements in the SGRQ; CAT; and the TDI, focal score, compared with SoC. The EXAcerbations of Chronic Pulmonary Disease Tool (EXACT)-PRO, dyspnea domain, was significantly improved in the Zephyr valve group. The outcome of the analysis concluded that individuals with severe hyperinflated emphysema achieving lung volume reductions with Zephyr valves experience improvements in multidimensional scores for breathlessness, activity, and psychosocial parameters out to at least 12 months.

Eberhardt et al. in 2021 reviewed 1-year results from an IMPACT (Informing the Pathway of COPD Treatment) randomized clinical trial of 93 individuals who underwent either bronchoscopic lung volume reduction with Zephyr valves or SoC treatment. Individuals with the Zephyr valve were assessed at 3, 6, and 12 months. Individuals receiving SoC were assessed at 3 and 6 months, and were then offered crossover to Zephyr valve treatment. At 6 months, there was significantly more response from the Zephyr valve versus the SoC group. The clinical benefits were persistent at 12 months. The percentage of individuals with respiratory serious adverse events was higher in the Zephyr valve group compared with SoC during the first 30 days postprocedure but not statistically different for the Zephyr valve and SoC groups from 31 days to 6 months, and was stable in the Zephyr valve group from 6 to 12 months. There were two deaths in the SoC group in the 31-day to 6-month period and none in the Zephyr valve group out to 12 months. The authors concluded that bronchoscopic lung volume reduction with Zephyr valves in individuals with severe homogeneous emphysema and little to no collateral ventilation provides clinically meaningful change from baseline in lung function, quality of life, exercise capacity, dyspnea, and the BODE index at 6 months with benefits maintained out to 12 months.

Despite the IMPACT trial studying a population of individuals with homogenous emphysema, it does not follow a control group out to 12 months. Although the results of the treatment group are encouraging, comparison to a control group is necessary to establish the safety and effectiveness of Zephyr among this population (as has been conducted in the heterogeneous emphysema population).

Buttery et al. in 2023 conducted a multicentered, randomized controlled trial (RCT), of 88 individuals eligible for either Zephyr or lung volume reduction surgery in the United Kingdom. Blinding of the participants and trial coordinator was not feasible, although the primary assessor was blinded. The primary outcome was the difference between groups in the i-BODE score at 12 months. The i-BODE score is a composite measure of body mass index, FEV₁, Medical Research Council dyspnea score, and exercise capacity. Of the 49 individuals with complete end-point data, there was no difference between the two groups in i-BODE scoring. The trial showed similar safety profiles at 12 months between the groups.

Spiration® Valve System

In 2019, Criner et al. conducted the pivotal trial EMPROVE (Improving Lung Function in Severe Heterogenous Emphysema with the Spiration Valve System)  evaluating the safety and effectiveness of the Spiration Valve System (SVS) of 174 individuals with emphysema, randomized 2:1 to SVS or standard medical management. The primary effectiveness outcome was the difference between groups in FEV₁ at 6 months. Additional endpoints consisted of the difference in number of FEV1 “responders," SGRQ, and exercise capacity among others. The primary safety endpoint was the incidence of thoracic serious adverse events at 6 months. The effectiveness outcome was met, as the average improvement in FEV₁ was significantly greater among the treatment group compared to the control group (difference, 0.10 L). At 6 months, the incidence of serious adverse events was significantly greater among the treatment group compared to the control group (19% greater).

In 2024, Criner et al. 2024 reviewed 24-month data from the EMPROVE trial. The primary outcome was the difference in FEV₁ between SVS-treated and control groups. Additional outcomes included SGRQ, modified Medical Research Council dyspnea scale, and COPD Assessment Test, among others. The primary outcome was met, as a statistically significant improvement in FEV₁ was observed in the treatment group compared to the control group. However, the percentage of “responders," defined as a 15% or greater improvement, was not statistically significantly different between the groups. No difference was observed in serious adverse events in the 12- to 24-month follow-up period. 

CLINICAL GUIDELINES 

The National Institute for Health and Care Excellence (NICE) issued the following recommendations in 2017 on endobronchial valve insertion to reduce lung volume in emphysema:

• Current evidence on the safety and efficacy of endobronchial valve insertion to reduce lung volume in emphysema is adequate in quantity and quality to support the use of this procedure provided that standard arrangements are in place for clinical governance, consent, and audit.

• Individual selection should be done by a multidisciplinary team experienced in managing emphysema, which should typically include a chest physician, a radiologist, a thoracic surgeon, and a respiratory nurse.

• Individuals selected for treatment should have had pulmonary rehabilitation.

• The procedure should only be done to occlude volumes of the lung where there is no collateral ventilation, by clinicians with specific training in doing the procedure.

In 2018 with an update in 2019, NICE guidance on the diagnosis and management of COPD included the following recommendations on lung volume reduction procedures:

• Offer a respiratory review to assess whether a lung volume reduction procedure is a possibility for people with COPD when they complete pulmonary rehabilitation and at other subsequent reviews, if all of the following apply:
  

• The individual has severe COPD, with FEV₁ less than 50% and breathlessness that affects their quality of life despite optimal medical treatment

• Does not smoke

• Can complete a 6MWD of at least 140 m (if limited by breathlessness)
  

• At the respiratory review, refer the individual with COPD to a lung volume reduction multidisciplinary team to assess whether lung volume reduction surgery or endobronchial valves are suitable if they have:
  

• hyperinflation, assessed by lung function testing with body plethysmography 
  

• emphysema on unenhanced CT chest scan 
  

• optimized treatment for other comorbidities
  

The 2023 Global Initiative for Chronic Obstructive Lung Disease (GOLD) publication makes the following statements on lung volume reduction interventions:

• In selected individuals with heterogeneous or homogenous emphysema and significant hyperinflation refractory to optimized medical care, surgical or bronchoscopic modes of lung volume reduction (e.g., endobronchial one-way valves, lung coils or thermal ablation) may be considered.
  

• In select individuals with advanced emphysema refractory to optimized medical care, surgical or bronchoscopic interventional treatments may be beneficial

For individuals with pulmonary air leaks who receive bronchial valves, the evidence includes the case series and a prospective cohort observational study related to the HDE for the Spiration IBV Valve device. Relevant outcomes are overall survival, symptoms, functional outcomes, quality of life, and treatment-related morbidity. Other reports are small series of heterogeneous individuals. There are no comparative data with alternatives. 

For individuals who have severe or advanced emphysema who receive bronchial valves, the evidence includes RCTs and systematic reviews. Relevant outcomes are overall survival, symptoms, functional outcomes, quality of life, and treatment-related morbidity. In individuals with severe emphysema and low collateral ventilation, RCTs provide evidence of clinically meaningful benefit for bronchial valves compared to standard medical management on measures of lung function, exercise tolerance, and quality of life, although confidence in these results is low due to study limitations including a lack of blinding and wide confidence intervals around estimates of effect. Across studies, there was an increased risk of serious procedure-related adverse events compared to usual care, including pneumothorax, occurring in up to 27% of participants. The potential benefits of the procedure are believed to outweigh the demonstrated harms in individuals​ with advanced and medically refractory emphysema, and offer a less-​invasive alternative to lung volume reduction surgery.