Neutrophil elastase (NE) has the potential to serve as a direct biomarker for neutrophilic inflammation in predicting the risk of future exacerbations (24), although it is not yet widely utilized in daily clinical practice. As a major protease with significant hydrolytic activity, NE plays a crucial role in the progression of bronchiectasis. Studies have confirmed that NE is overexpressed in bronchiectasis, representing a key risk factor for the development of structural lung damage and decreased lung function (30). Additionally, NE is associated with airway mucus hypersecretion and impaired mucociliary clearance (31), both of which are critical risk factors for bacterial colonization and contribute to the foundation of chronic inflammation (32). NE plays a crucial role in the onset and progression of bronchiectasis through various pathways. Even a single NE inhibition strategy can impact the entire complex protease network. As a result, NE is considered a potential therapeutic target, and several NE inhibitors have been developed. Sivelestat sodium is the only NE inhibitor currently approved for clinical use and is utilized primarily in patients with COVID-19 in China (33). However, there is a notable lack of relevant research concerning its application in bronchiectasis. AZD9668, an oral NE inhibitor, has undergone a phase II trial that failed to demonstrate a significant difference in sputum NE activity between the experimental and observation groups post-treatment. Nonetheless, the study indicated that lung function in the experimental group improved somewhat, and sputum inflammatory marker levels tended to decrease (34). BAY85-8501, which is highly selective and specific for NE, did not result in any adverse reactions during the phase I trial. In the phase IIa clinical trial, two groups of bronchiectasis patients were administered either a placebo or BAY85-8501. The findings revealed no significant changes in sputum NE activity or lung function between the two groups following treatment; however, blood NE activity in the treatment group decreased significantly (35). Researchers have hypothesized that the oral administration method may lead to insufficient drug concentrations in the lungs, contributing to low clinical efficacy. Consequently, they developed an inhaled NE inhibitor. CHF6333 is an NE inhibitor delivered as a dry powder inhaler and offers opportunity to assess the importance of higher lung concentrations than serum. In vitro experiments have demonstrated that CHF6333 exhibits high selectivity for NE (36). A phase Ib trial of CHF6333 in patients with cystic fibrosis and bronchiectasis concluded in 2021; however, no data are currently available (NCT04010799: 2019-07-08; US Clinical Trials Registry). Additionally, a new clinical trial is currently recruiting participants (NCT06166056). POL6014 is a novel inhaled inhibitor that has undergone phase I trials, which indicated that it is safe, well tolerated, and achieves high drug concentrations in the lungs. Furthermore, it has been shown to inhibit NE activity in sputum from patients with cystic fibrosis following a single administration (37).

Serendex has developed a nebulizer containing Molgramostim, a non-glycosylated form of recombinant human granulocyte-macrophage colony-stimulating factor (GM-CSF). While most therapies aim to downregulate neutrophils to prevent protease damage, inhaled GM-CSF aims to restore or enhance neutrophil bactericidal function, which may be beneficial for clearing persistent infections like NTM A phase 1 randomized, double-blind, placebo-controlled clinical trial (NCT02468908) involving healthy adults has been completed in the UK. This trial evaluated the safety and tolerability of both single ascending doses and multiple ascending doses of Molgramostim in humans. The results indicated that inhaled Molgramostim was well tolerated by the subjects, demonstrated minimal absorption into the bloodstream, and significantly affected white blood cell counts within the normal range. The most commonly reported adverse event was cough. Patients with bronchiectasis are particularly susceptible to non-tuberculous mycobacterial pulmonary disease (NTM-PD). Additionally, an open-label, single arm pilot trial (OPTIMA) was designed to assess the efficacy and safety of inhaled GM-CSF (Molgramostim nebulized solution) in treating NTM-PD in adults with non-CF bronchiectasis (38). Overall, the study found that the study drug was safe and reasonably well tolerated, suggesting that treatment with inhaled Molgramostim may represent a promising therapeutic option.

Although these data have not fully demonstrated the exact efficacy of NE inhibitors in the treatment of bronchiectasis, researchers continue to explore and optimize the therapeutic strategies for NE inhibitors, including the development of inhaled NE inhibitors to increase the concentration of the drug in the lungs and thus improve the clinical efficacy. Currently, the development of multifunctional drugs that not only block the signaling pathways associated with NE but also possess anti-protease and anti-inflammatory properties and promote airway repair is considered a promising avenue for future research.

A different strategy, as opposed to the conventional inhibition of NE, includes the use of medications that focus on the activation of serine proteases within the bone marrow. Cathepsin C (CTSC), which is also referred to as DPP-1, functions as a lysosomal cysteine protease that plays a crucial role in the maturation of neutrophils. This enzyme is responsible for the cleavage of several key proteins, including NE, cathepsin G, and proteinase 3, during the activation process of neutrophils. As neutrophils mature, the activated serine proteases that they produce are subsequently packaged into granules within these cells. Once mature neutrophils enter the systemic circulation, they are able to carry out their functions in the immune response (39). Consequently, the implementation of CTSC inhibitors has the potential to impede the activity of neutrophil serine proteases within airways, thereby possibly influencing inflammatory responses in these regions. As of June 2020, the U.S. FDA has designated brensocatib, a CTSC inhibitor, as a breakthrough therapy for adult non-cystic fibrosis bronchiectasis. Brensocatib, an oral reversible DPP-1 inhibitor, indirectly inhibits NE activity by blocking neutrophil serine protease activation. A phase II clinical trial for bronchiectasis revealed that patients receiving oral treatment with varying doses of brensocatib experienced a significant reduction in sputum NE activity, as well as an extended time to the first exacerbation, suggesting that brensocatib may offer clinical benefits in reducing inflammation and preventing exacerbations (12). The drug has completed the Phase III development for the treatment of bronchiectasis (NCT04594369). The Phase 3 ASPEN trial results, published in the New England Journal of Medicine in 2025, demonstrated that brensocatib significantly reduced the annual rate of pulmonary exacerbations and prolonged the time to the first exacerbation compared to placebo (40). BI 1291583 is a novel, highly effective and selective DPP-1 inhibitor that is currently being investigated as a potential disease-modifying therapy in patients with bronchiectasis (41). Results from recent phase II trials showed that treatment with BI 1291583 can alleviate deterioration in adult patients with bronchiectasis (NCT05238675) (42). Following these promising results, several additional trials are now in progress (NCT05865886, NCT05846230). HSK31858 Is an oral, reversible DPP1 inhibitor developed by Haisco, being tested for the treatment of noncystic fibrosis bronchiectasis. HSK31858 demonstrated good safety and tolerability in phase I clinical trials (NCT05663593) and dose dependently suppressed whole blood NE activity. The phase II of the results have not yet been fully made public and it is currently in phase III clinical trials (NCT06660992). In addition, there are several other DPP-1 inhibitors currently in development. Overall, these DPP-1 inhibitors, which act by blocking the maturation and activation of neutrophil serine proteases within the bone marrow, are in different stages of clinical trials. Most have yielded promising results, offering potential new systemic options for reducing the protease burden in bronchiectasis.

Distinct from the upstream mechanism of DPP-1 inhibition, alpha 1-antitrypsin (A1AT, also known as alpha 1-protease inhibitor) functions as a direct, competitive inhibitor of neutrophil elastase (NE). It is currently being investigated for its potential to directly neutralize active proteases in the airways, mitigate inflammation, and potentially enhance neutrophil function (NCT05582798). This direct protease-inhibition strategy provides a complementary approach to targeting the inflammatory cascade in patients with bronchiectasis.

A different strategy to alleviate neutrophilic inflammation focuses on directly reducing the influx of neutrophils into affected tissues. The chemokine receptor CXCR2 is pivotal in this process, as its activation by chemokines like CXCL1 and CXCL8 facilitates neutrophil migration. Research has demonstrated that CXCR2 antagonism, as exemplified by the oral CXCR2 antagonist AZD5069 in a clinical trial targeting CXCR1, effectively reduces neutrophil recruitment to the lungs without impairing their immune functions. Specifically, in a study with bronchiectasis patients receiving AZD5069 at 80 mg twice daily for 28 days, a significant 69% reduction in sputum neutrophil counts was observed compared to a placebo control group (43). While exacerbations were reported in both groups without significant difference, four cases of treatment discontinuation due to infection (one pneumonia and three bronchiectasis exacerbations) were noted in the AZD5069 group. Additional studies with CXCR2 antagonists in healthy volunteers and nonhuman primates demonstrated a rise in in blood cytokines, including CXCL1, CXCL8 and CXCR2 ligands, post-treatment, though the clinical significance of this increase is unclear. Furthermore, the 28-day treatment duration may be insufficient to assess all clinically significant effects, highlighting the need for larger-scale studies. Notably, other CXCR2-targeting compounds did not yield positive results in clinical trials (NCT03250689). Alternatively, Roflumilast, a phosphodiesterase 4 (PDE-4) inhibitor, reduces PDE-4 production, suppresses neutrophil chemotaxis and migration, and promotes cell apoptosis for anti-inflammatory effects (44). Currently, its anti-inflammatory effect in stable noncystic bronchial fibrosis is being evaluated in a phase II trial for 12 weeks (NCT04322929) in single-arm, open label, study of 42 patients; no results are available yet.

Approximately 20% of patients with bronchiectasis, excluding those with asthma, allergic bronchopulmonary aspergillosis, or chronic sinusitis with nasal polyps, exhibit eosinophilia (defined as > 3% or 300/μL), a condition referred to as eosinophilic bronchiectasis (45). Notably, eosinophilic inflammation in bronchiectasis does not imply the absence of neutrophil inflammation (46). The precise role of eosinophils in these patients remains unclear. It is hypothesized that eosinophils may possess bactericidal and antiviral properties against the pathogenic microorganisms commonly associated with bronchiectasis. This study revealed a correlation between blood eosinophil levels and the microbiome. Elevated eosinophil levels are associated with accelerated progression of Pseudomonas aeruginosa infection, whereas low eosinophil levels are predictive of severe bronchiectasis and an increased risk of mortality (45), thereby establishing new indicators for disease subtypes. Patients diagnosed with eosinophilic bronchiectasis frequently require inhaled corticosteroids (47); however, the role of Th2-dominant (eosinophilic) inflammation is becoming increasingly recognized (45). Consequently, other anti-Th2 drug treatments have demonstrated greater efficacy (48). In addition, benralizumab is an interleukin-5 receptor-directed cytolytic monoclonal antibody that induces direct, rapid, and massive eosinophil depletion through antibody-dependent cytotoxic activity (49). Retrospective studies have shown a certain relieving effect of benralizumab on bronchiectasis (50).

Commonly used injectable vaccines include the influenza vaccine and the pneumococcal vaccine. Influenza vaccination can prevent secondary lung infections caused by the influenza virus. Although there is a lack of robust specific evidence regarding the benefits of the influenza vaccine for patients with bronchiectasis, indirect evidence suggests that annual influenza vaccination can reduce mortality and morbidity and reduce healthcare costs in high-risk groups (51). A randomized controlled study demonstrated that the administration of the 23-valent pneumococcal vaccine can decrease the frequency of acute exacerbations (52). Furthermore, a study conducted by Japanese researchers involving 105 patients with chronic respiratory diseases, including 20 patients with bronchiectasis, revealed that vaccination with both the influenza vaccine and the 23-valent pneumococcal vaccine can prevent lower respiratory tract infections in these patients (53). Consequently, the bronchiectasis guidelines from the United Kingdom and Saudi Arabia, along with the expert consensus in China, recommend vaccination for patients to mitigate the onset of bronchiectasis (54, 55).

The bacterial lysate OM-85 BV is an immunomodulator widely utilized to prevent acute attacks or exacerbations of COPD, chronic bronchitis, respiratory infections, chronic sinusitis, and other related conditions (56). The primary components of OM-85 BV include freeze-dried lysates from eight of the most prevalent pathogenic bacteria associated with respiratory tract infections, namely, Haemophilus influenzae, Diplococcus pneumoniae, Klebsiella pneumoniae, Klebsiella odorifera, Staphylococcus aureus, Viridans streptococci, Streptococcus pyogenes, and Neisseria catarrhalis. Currently, small-sample observational studies have confirmed the preventive effects of Panfusu in patients with bronchiectasis. Furthermore, a double-blind, placebo-controlled randomized clinical trial assessing the efficacy of OM-85 BV in preventing acute attacks in Chinese patients with bronchiectasis is underway (NCT01968421). The results of this study aim to substantiate its preventive effects on acute bronchiectasis attacks through evidence-based medicine (57).

Recent studies have confirmed the immunomodulatory effects of statins (58). Notably, high-dose atorvastatin has been shown to significantly reduce cough in bronchiectasis patients who do not have a Pseudomonas aeruginosa infection (59). Bedi et al. conducted a double-blind, crossover randomized controlled trial demonstrating that atorvastatin can alleviate patient symptoms by reducing systemic inflammation in individuals with bronchiectasis infected by Pseudomonas aeruginosa (60). (NCT01299194). However, this study had several limitations, including low statistical power for secondary efficacy endpoints, a short study duration, and a lack of matching between the two groups. Despite these limitations, the results support the potential benefits of statins as anti-inflammatory agents in patients with chronic bronchiectasis infections. Nonetheless, longer and larger multicenter studies are necessary to further validate these findings.

Published guidelines identify airway clearance as a critical treatment for bronchiectasis, although the supporting evidence remains relatively weak (83, 84, 93). Research on epithelial dysfunction in bronchiectasis is limited compared with that in cystic fibrosis, where CFTR corrector therapy has shown promising results (94). CFTR mutations are controversial noncystic fibrosis bronchiectasis, with studies showing varying frequencies of these mutations (95–97). However, CFTR dysfunction may play a role in some cases, making CFTR correction a potential treatment option (98). Inhibitors of the epithelial sodium channel (ENaC) represent a potential therapeutic strategy to facilitate mucus rehydration by hindering excessive sodium absorption. While the rationale for ENaC inhibition has been extensively explored in cystic fibrosis (CF) due to its role in CFTR-dependent secretion, it is critical to distinguish these mechanisms from the pathophysiological environment of non-CF bronchiectasis. Clinical evidence in the bronchiectasis population remains limited; for instance, a phase II clinical trial of the ENaC inhibitor VX-371 failed to demonstrate significant improvements in the percentage of predicted forced expiratory volume (ppFEV1), although the treatment was generally well-tolerated. Similar challenges in demonstrating clear clinical benefits have been observed with other agents like BI 1265162, contributing to ongoing debates regarding ENaC as a viable therapeutic target in these populations. A major breakthrough in the management of airway clearance was provided by the CLEAR trial (2025) (99). This landmark study evaluated the efficacy of hypertonic saline versus carbocisteine specifically in patients with bronchiectasis; however, the results demonstrated no significant benefit in exacerbation reduction or quality of life with either the systemic mucolytic or nebulized hypertonic saline. By providing high-quality comparative data for non-CF cohorts, the CLEAR trial underscores the necessity of moving toward evidence-based, precision airway clearance therapies tailored specifically for the bronchiectasis population.

In addition to CFTR and ENaC-related treatments, several novel therapies are currently under investigation. ARINA-1 is a new nebulized product composed of ascorbic acid, glutathione, and bicarbonate that operates through a mechanism independent of CFTR, offering a potential new treatment for mucus clearance disorders in cystic fibrosis (100). Recently, a phase IIa clinical trial of ARINA-1 demonstrated positive results in adult subjects with noncystic fibrosis bronchiectasis (NCFBE) characterized by excess mucus and cough (NCT05495243). Hypertonic saline delivered via nebulization serves as a mucoactive therapy and has shown promising advantages for individuals diagnosed with bronchiectasis. In a limited-scale investigation, researchers reported that daily nebulization of a 7% saline solution led to improvements in lung function and quality of life (101). Furthermore, inhaled dry powder mannitol is utilized in the treatment of cystic fibrosis and has been shown to enhance ciliary clearance, although its precise mechanism of action remains unclear (102, 103). Another innovative biophysical therapeutic agent, S-1226, employs carbon dioxide (CO₂)-rich air in combination with aerosolized perfluorocarbons (PFOB) to promote airway dilation, enhance mucus clearance, and improve blood oxygenation. Preliminary efficacy results indicate that S-1226 may positively impact the management of cystic fibrosis-related lung disease; however, further clinical trials are necessary to validate these findings (NCT03903913). Finally, CSL-787 is a nebulized immunoglobulin formulation currently in development for the treatment of noncystic fibrosis bronchiectasis (NCT04643587). The emergence of these new therapies offers renewed hope for the management of bronchiectasis and cystic fibrosis.

Nonpharmacological methods of airway clearance include active recirculation breathing techniques, autogenic drainage (which involves a controlled expiration rate and depth to facilitate secretion mobilization), slow expiration with the glottis open in the lateral decubitus position, and the application of positive expiratory pressure. Additionally, oscillation devices and high-frequency chest wall oscillation are utilized (21). The advantages of these treatments lie in their independence for patients, as they are generally safe and straightforward to learn (104). Observational studies focusing on pulmonary rehabilitation and exercise programs carried out in both Australia and Italy have demonstrated significant improvements in various physiological measurements, including the 6-minute walk distance and quality of life related to health (105, 106).