OM-85 and Respiratory Symptoms in Korean Chronic Obstructive Pulmonary Disease: A Multicenter Observational Study

Article information

Tuberc Respir Dis. 2026;89(1):55-64

Publication date (electronic) : 2025 September 4

doi : https://doi.org/10.4046/trd.2025.0105

, Tae-Ok Kim ¹, Hong-Joon Shin ¹, Hak-Ryul Kim ², Ki-Eun Hwang ², Sung Ho Yoon ³, Seoung Ju Park ⁴, Yong-Soo Kwon^,¹

¹Department of Internal Medicine, Chonnam National University Hospital, Chonnam National University Medical School, Gwangju, Republic of Korea

²Division of Pulmonary Medicine, Department of Internal Medicine, Wonkwang University School of Medicine, Iksan, Republic of Korea

³Department of Pulmonology and Critical Care Medicine, Chosun University Hospital, Gwangju, Republic of Korea

⁴Department of Internal Medicine, Jeonbuk National University Hospital, Jeonbuk National University Medical School, Jeonju, Republic of Korea

Address for correspondence Yong-Soo Kwon Department of Internal Medicine, Chonnam National University Hospital, Chonnam National University Medical School, 42 Jebong-ro, Dong-gu, Gwangju 61469, Republic of Korea Phone 82-62-220-6575 Fax 82-62-225-8578 E-mail yskwon@jnu.ac.krt

Received 2025 June 21; Revised 2025 August 14; Accepted 2025 September 2.

Abstract

Background

Although OM-85 may lessen respiratory symptoms and reduce acute exacerbations in chronic obstructive pulmonary disease (COPD), proof of its overall effectiveness remains incomplete.

Methods

This prospective, observational, single-arm study was conducted at four university hospitals in South Korea from June 2022 to December 2023. Adults with spirometry-confirmed COPD who were prescribed OM-85 were enrolled, and followed for 6 months (3-months treatment, 3-months observation). Symptoms and health-related quality of life were assessed using the modified Medical Research Council scale, COPD Assessment Test (CAT), and St. George’s Respiratory Questionnaire (SGRQ). Acute exacerbations and adverse events were recorded.

Results

Of the 323 patients analyzed (mean age 73.3±7.8 years; 83.9% male), 39.0% had baseline CAT ≥10. Patients in this group experienced markedly greater and sustained improvements in both CAT and SGRQ scores compared with those with CAT <10 (p for interaction <0.001 for both), and the magnitude of these changes exceeded the minimal clinically important difference (CAT: −3.21±3.85; SGRQ: −10.42±14.87 at 6 months), indicating clinically meaningful symptom relief. Among these patients, achieving SGRQ responder status at 6 months was negatively associated with an increased frequency of acute exacerbations (odds ratio, 0.246; 95% confidence interval, 0.050 to 1.207; p=0.084), showing a nonsignificant trend. OM-85 was well tolerated, with only mild, reversible drugrelated adverse events.

Conclusion

OM-85 treatment resulted in meaningful improvements in symptoms and healthrelated quality of life, particularly among patients with more severe baseline symptoms, and was in general well tolerated.

Keywords: OM-85; Chronic Obstructive Pulmonary Disease; Symptom; Quality of Life

Introduction

Chronic obstructive pulmonary disease (COPD) is a highly prevalent respiratory disorder that affects an estimated 210 million individuals worldwide [1]. In Korea, the 2012 Korea National Health and Nutrition Examination Survey reported a prevalence of 15.5% among individuals aged ≥40 years, and 57.6% among men aged ≥70 years [2]. The Global Burden of Disease Study by the World Health Organization ranked COPD as the sixth leading cause of death globally in 1990, rising to third in 2020. It is projected to become the fourth leading cause of death by 2030. The disease burden, as measured by disability-adjusted life years, has also shown a steady increase over recent decades [3]. Beyond its clinical impact, COPD imposes a substantial economic burden, through increased healthcare utilization and productivity loss [4].

COPD is characterized by persistent, irreversible airflow limitation due to an abnormal inflammatory response that affects the small airways and alveolar structures [1]. This inflammation is triggered by exposure to noxious particles or gases, such as cigarette smoke, and involves the activation of inflammatory cells, including macrophages, neutrophils, and lymphocytes. T-cell–mediated inflammatory responses play a central role in this process, and can persist even after cessation of exposure to causative agents, Therefore, T-cell–driven inflammation is considered a key factor in COPD pathogenesis [5,6].

OM-85 is an oral immunomodulatory agent composed of lyophilized bacterial lysates from 21 different bacterial strains. It has demonstrated the ability to reduce inflammation, while enhancing host immunity against respiratory infections [7-11]. Several studies have shown that OM-85 reduces the frequency of acute exacerbations in COPD, consequently lowering the use of antibiotics and systemic corticosteroids [12-20]. However, most prior investigations emphasized exacerbation prevention, with comparatively limited attention to symptom control and health-related quality of life (HRQoL). Symptom relief is a core treatment goal in COPD, because it directly improves daily functioning, and in contemporary guidance is recognized—alongside future risk reduction—as a primary target of therapy [1]. Importantly, higher day-to-day symptom burden is associated with worse HRQoL and greater disease impact [21], and specific symptom profiles (e.g., prominent morning symptoms) independently predict a higher risk of future exacerbations [22]. Broader syntheses similarly link greater symptom intensity to increased exacerbation risk and healthcare utilization [23]. Thus, improving symptoms and HRQoL is not merely palliative; it may also mitigate downstream clinical risk by reducing susceptibility to infection-triggered worsening, supporting activity and self-management, and stabilizing disease trajectories [1,21-23].

Against this background, the present study evaluated the efficacy of OM-85 for symptom control in patients with COPD, and explored whether symptom improvement is associated with the incidence of acute exacerbations. We hypothesized that OM-85 would yield clinically meaningful gains in symptoms and HRQoL—in particular, among patients with higher baseline symptom burden—and that symptom responders would show a lower risk of subsequent exacerbation events.

Materials and Methods

1. Population

This prospective, observational, single-arm study was conducted from June 1, 2022, to December 31, 2023, at four South Korean university hospitals: Chonnam National University Hospital, Chosun University Hospital, Chonbuk National University Hospital, and Wongkang University Hospital. Eligible participants were adults aged ≥18 years with a diagnosis of COPD, confirmed by post-bronchodilator forced expiratory volume in 1 second/forced vital capacity <−0.70 within the past year. Patients who had been prescribed and had taken OM-85 for a defined period were enrolled. Exclusion criteria included known hypersensitivity to OM-85 or its components, drug contraindications, or refusal to provide informed consent.

2. Protocol and sample size

OM-85 (Broncho–Vaxom, Aju Pharm Co. Ltd., Seoul, Korea), a lyophilized bacterial lysate, was administered as a 7 mg capsule once daily in the morning while fasting. The study period included a 3-month treatment phase, followed by a 3-month observation phase. During both phases, patients were evaluated monthly for symptoms, quality of life, acute exacerbations, and adverse events (AEs) (Supplementary Table S1).

The sample size was calculated based on a previous Korean epidemiological investigation reporting that approximately 60% of COPD patients experience persistent respiratory symptoms [24]. It was hypothesized that treatment with OM-85 would lead to a ≥12% improvement in symptom rates from baseline. To detect this effect with 80% power at a two-sided α of 0.05, the minimum required sample size was 540 participants. Allowing for a 10% attrition rate, the final target sample size was adjusted to 600 participants. Each of the four participating institutions aimed to recruit 150 patients.

3. Outcomes

The primary outcomes of this study were the change in respiratory symptoms and quality of life during treatment. HRQoL indices were assessed using the modified Medical Research Council (mMRC) dyspnea scale and COPD Assessment Test (CAT), while quality of life was measured using the St. George’s Respiratory Questionnaire (SGRQ). The SGRQ was analyzed in three domains (symptoms, activity, and impacts), and SGRQ% refers to the percentage score calculated according to the official SGRQ scoring algorithm, with higher scores indicating greater impairment in health status. For responder analyses, the minimal clinically important difference (MCID) was defined as a reduction of ≥2 points from baseline for the CAT, and ≥4 points for the SGRQ. The secondary outcome was the incidence of acute exacerbations, defined as a sudden worsening of respiratory symptoms—such as dyspnea, cough, or sputum volume and purulence—beyond normal daily variation, requiring additional treatment, which treatment included antibiotics, systemic corticosteroids, or both [1].

4. Safety assessment

Safety was assessed by monitoring AEs, defined as any undesirable medical occurrence following the administration of the investigational product, regardless of the causal relationship. This included new symptoms, worsening of preexisting conditions, or abnormal laboratory findings. Adverse drug reactions (ADRs) were defined as harmful and unintended responses for which a causal link to OM-85 could not be excluded. Serious AEs/ADRs were defined as lifethreatening events, hospitalizations or their prolongation, permanent disability, or other medically significant conditions. A suspected serious adverse reaction was defined as a serious ADR differing in nature or severity from known product characteristics, and which could not be excluded as being related to the investigational product.

Causality was assessed based on timing, alternative explanations (e.g., comorbidities or concomitant medications), and response to drug discontinuation or readministration. Events were categorized as unlikely, possible, probable, or definite. The severity of each AE was graded according to the general principles of the Common Terminology Criteria for Adverse Events (CTCAE), as follows:

• Mild: transient and easily tolerated, with no interference in daily activities, and no need for medical intervention.

• Moderate: symptoms causing some interference with daily activities and requiring minimal medical intervention, but not lifethreatening.

• Severe: medically significant symptoms that are potentially lifethreatening, or result in hospitalization or disability.

5. Statistical analysis

Continuous variables were expressed as the mean±-standard deviation, while categorical variables were presented as the count (%). For between-group comparisons, t-tests were used for continuous variables, and Pearson’s chi-squared or Fisher’s exact test for categorical variables. Repeated-measures analysis of variance (ANOVA) was used to evaluate within-subject changes over time for continuous outcomes, while a generalized estimating equation approach was applied for nominal variables.

Binary logistic regression was performed to identify factors associated with the outcome. Variables with a p-value <0.2 in the univariable analysis were initially considered for inclusion. In addition, clinically important factors previously reported to be associated with the outcome were included, regardless of their univariable significance. A backward selection method was applied to derive the final multivariable model. A p-value <0.05 was considered statistically significant.

6. Ethics statement

This study was conducted in accordance with the principles of the Declaration of Helsinki, and was approved by the Institutional Review Boards and Ethics Committees of all participating institutions, including Chonnam National University Hospital (IRB No. BCRE22159). Written informed consent was obtained from all participants prior to their enrollment.

Results

Although the target sample size was 600, the enrollment rate was slower than anticipated, and the recruitment of additional centers was not feasible. Consequently, the study was terminated earlier than planned. A total of 332 patients were initially enrolled; of these, four withdrew informed consent and five were lost to followup with no subsequent records, resulting in a final study population of 323 patients included in the analysis.

Among these 323 patients, the mean age was 73.3± 7.8 years, and 83.9% (n=266) were male. A history of smoking was reported in 277 patients (85.8%), while 104 (32.2%) had a previous history of tuberculosis (TB), which included all individuals with a history of previous TB treatment, as well as those with imaging findings suggestive of old TB lesions. Common comorbidities included cardiovascular disease in 153 patients (47.4%), and diabetes mellitus in 75 patients (23.2%). Most patients (94.4%) were receiving inhaled bronchodilator therapy: 67 (20.7%) with long-acting muscarinic antagonists (LAMA) alone, 193 (59.8%) with combination therapy of a long-acting beta-2 agonist (LABA) and a LAMA, and 36 (11.1%) with an inhaled corticosteroid and LABA. Among the participants, 44.6% (n=144) had mMRC dyspnea grade ≥2, 39.0% (n=126) had CAT score ≥10, and 57.6% (n=186) of patients had SGRQ score ≥25. A previous history of AE in the previous 6 months was reported in 9.1% (29/319) of patients (Table 1).

Table 1.

Baseline characteristics

Table 2 summarizes symptom-related outcomes at 3 and 6 months following OM-85 administration. No statistically significant change was observed in the mMRC dyspnea scale. The mean SGRQ score decreased from 34.74±22.08 at baseline, to 33.78±22.25 at 3 months (p=0.234), and 32.72±23.48 at 6 months (p=0.074), showing a trend toward improvement over time without statistical significance. Although CAT scores were significantly reduced at both 3 and 6 months compared to baseline (from 9.81±7.79 to 8.97±7.58 at 3 months, p=0.001; and to 8.69±7.35 at 6 months, p=0.001), the magnitude of change did not reach the MCID of 2 points required to be considered a CAT responder.

Table 2.

Comparison of symptoms and quality of life scores between baseline and 3 or 6 months of treatment in 323 COPD patients who received OM-85 for 3 months

Multivariable logistic regression analysis was performed to identify risk factors for acute exacerbation in all patients receiving OM-85. Regardless of treatment response, a baseline CAT score ≥10 was a significant COPD-related factor associated with acute exacerbation (Supplementary Table S2). In a separate analysis assessing factors associated with increased AE frequency after treatment—defined as a higher frequency of AE during the study period compared to before—a baseline CAT score ≥10 was also a significant predictor (Supplementary Table S3).

Therefore, a subgroup analysis for patients with baseline CAT score ≥10 was conducted to assess the association between OM−85 response and exacerbation risk.

Compared to patients with baseline CAT <10, those with CAT ≥10 had a significantly lower body mass index (22.16±3.36 vs. 23.10±3.25, p=0.014), a higher prevalence of asthmatic components (24.6% vs. 6.1%, p<0.001), and were more likely to receive phosphodiesterase-4 inhibitors (9.5% vs. 3.6%, p=0.026). Use of LAMA monotherapy was more common in the CAT <10 group (26.9% vs. 11.1%, p<0.001). Other baseline characteristics, including age, sex, smoking status, comorbidities, pulmonary function, and history of exacerbation, did not differ significantly between the groups (Supplementary Table S4).

Table 3 presents the comparison of clinical outcomes according to baseline CAT scores. Both groups showed improvement over time (p for time effect <0.001), with a significantly greater reduction over time in the CAT ≥10 group (p for interaction <0.001). Although no significant time-by-group interaction was observed for responder rates (p=0.749), the CAT ≥10 group consistently demonstrated a higher proportion of responders compared to the CAT <10 group (p<0.001).

Table 3.

Comparison of clinical outcomes according to baseline CAT ≥10

Also, SGRQ scores were significantly higher in the CAT ≥10 group across all time points (p for group effect <0.001), while both groups showed improvement over time (p for time effect=0.014), with a significantly greater reduction over time in the CAT ≥10 group (p for interaction <0.001). A significant time-by-group interaction was also observed for SGRQ responder rates (p=0.032), indicating that the proportion of responders in the CAT ≥10 group increased more markedly over time.

The frequency of acute exacerbations was significantly higher in the CAT ≥10 group compared to the CAT <10 group (p for group effect=0.004), with both groups showing a significant decrease over time (p for time effect=0.001). However, there was no significant time-by-group interaction (p=0.966), indicating a similar pattern of reduction in both groups (Table 3).

In the multivariable analysis of factors associated with increased frequency of AE, no variable reached statistical significance. However, SGRQ response at 6 months showed a negative association with the outcome, with a trend toward significance (odds ratio, 0.246; 95% confidence interval, 0.050 to 1.207; p=0.084) (Table 4).

Table 4.

Factors associated with increased frequency of acute exacerbation in patients treated with OM-85 in baseline CAT ≥10

In the safety assessment, 23 AEs were reported in 23 patients (7.1%) comprising 10 mild, 10 moderate, and three severe cases. Causality assessment indicated that three mild cases (palpitations, decreased appetite, and tingling sensation) were possibly related to OM-85, while one moderate case (urticaria) was deemed probably related. All three severe cases were assessed as either unrelated, or unlikely to be related, to OM-85 (Table 5).

Table 5.

Adverse drug reactions in all chronic obstructive pulmonary disease patients who received OM-85 for 3 months

Discussion

In this multicenter, real-world observational study, a 3-month course of OM-85 was associated with significant improvements in symptom burden and HRQoL in patients with COPD. Critically, these clinically meaningful benefits, as measured by CAT and SGRQ scores exceeding the MCID, were most pronounced in the subgroup of patients with a high baseline symptom load (CAT score ≥10) population. In addition, among patients with a baseline CAT score ≥10, those who were SGRQ responders at 6 months tended to have a lower incidence of increased frequency of acute exacerbation, suggesting a potential association. These findings suggest that the potential therapeutic value of OM-85 in COPD management may be greatest when targeted toward this more symptomatic population. Our study’s emphasis on symptom-focused outcomes provides a unique perspective within the broader landscape of OM-85 research. The existing literature presents a mixed picture; while several meta-analyses and trials have reported benefits in reducing exacerbation frequency [13,16], other studies have shown modest or no significant effects [17,19,20]. This discrepancy may be partly explained by differences in study design and patient populations. Many previous trials focused primarily on exacerbation prevention as the primary endpoint, and often enrolled patients with milder or more heterogeneous baseline symptoms. In contrast, our results highlight that by prioritizing patients with a greater initial symptom burden, it is possible to observe significant improvements in quality of life. This underscores the importance of patient selection, and suggests that to better identify those most likely to benefit from OM-85, future trials should consider stratifying patients by symptom severity.

The sustained clinical improvements observed in our study, which persisted for 3 months post-treatment, are supported by the well-established immunomodulatory mechanisms of OM-85. As an oral bacterial lysate, OM-85 has been shown to stimulate a multifaceted immune response. Mechanistically, it enhances innate immunity by promoting the maturation of dendritic cells and the activation of macrophages [25,26], bolsters mucosal defense by increasing secretory immunoglobulin A production [11], and modulates T-cell–mediated adaptive immunity [8,27]. These integrated immune adaptations provide a strong biological rationale for why OM-85 could produce durable clinical benefits, offering a plausible mechanism that should be tested in controlled settings.

While our study was not powered to definitively assess exacerbation prevention, our findings align with previous research that suggests a link between symptom control and exacerbation risk [28-30]. A baseline CAT score ≥10 was a significant predictor of acute exacerbations, and although not reaching statistical significance, an improvement in SGRQ score at 6 months showed a trend toward being protective against an increased frequency of exacerbations (p=0.084). This observation supports the potential dual role of OM-85, a hypothesis that warrants investigation in larger, randomized controlled trials.

With respect to safety, OM-85 was generally well-tolerated, consistent with its established safety profile in prior large-scale studies [10,16]. The AEs reported were infrequent, and mostly mild. However, the occurrence of some clinically important respiratory events, though not definitively linked to the treatment, suggests that prudent clinical monitoring remains advisable.

These findings are consistent with the established safety profile of OM-85 from prior large-scale studies [10,16], and support its use as a safe adjunctive therapy for symptom control in COPD patients, with appropriate monitoring.

Despite the encouraging real-world data presented, our study has several notable limitations that warrant discussion. The primary constraint is its observational, single-arm design, which lacks a control group. This inherent limitation prevents us from definitively concluding that the observed clinical improvements are solely attributable to OM-85, as other contributing factors may have influenced the outcomes. Furthermore, the absence of strict criteria for OM-85 prescription and broad enrollment criteria introduce the possibility of selection bias. Attending physicians’ preferences may have influenced who received the treatment, potentially favoring patients with a history of frequent respiratory infections.

Second, the study was underpowered due to early termination, which limits the generalizability of the results. Notably, only a small proportion of patients had a previous history of acute exacerbations at baseline, thereby making it difficult to directly assess the preventive effect of OM-85 on acute exacerbations. To address this limitation, we performed an indirect analysis by evaluating factors negatively associated with the increase in acute exacerbation frequency during the study period among patients with a positive history of acute exacerbations prior to enrollment. However, this approach inherently limited our ability to directly assess the preventive effect of OM-85 on acute exacerbations.

Third, heterogeneity in baseline characteristics—such as Global Initiative for Chronic Obstructive Lung Disease (GOLD) stage, exacerbation history, and prior treatment—along with incomplete clinical data, may have introduced bias and affected patient classification, thereby limiting the interpretation of treatment outcomes. Broad enrollment criteria may also have led to selection bias, particularly due to variations in prescribing practices among physicians.

Finally, reliance on questionnaire-based outcomes (e.g., CAT, SGRQ, mMRC) without objective clinical parameters, such as pulmonary function tests or biomarkers, may limit the objectivity of the results.

In conclusion, in this multicenter, single-arm observational study, OM-85 was associated with improvements in symptom burden and HRQoL, with clinically meaningful gains confined to patients with higher baseline symptoms (i.e., CAT ≥10). The regimen was generally well tolerated over the 3-month course, though prudent monitoring is advised, given occasional clinically important respiratory events. No preventive effect on acute exacerbations was demonstrated. These hypothesis- generating findings support considering OM-85 as an adjunctive option for symptom control in selected COPD patients, and warrant confirmation in adequately powered, prospective randomized trials.

Notes

Authors’ Contributions

Conceptualization: Kwon YS. Methodology: Kwon YS. Formal analysis: all authors. Data curation: all authors. Funding acquisition: Kwon YS. Project administration: Kwon YS. Validation: Yoon CS, Kwon YS. Investigation: all authors. Writing - original draft preparation: Yoon CS, Kwon YS. Writing - review and editing: all authors. Approval of final manuscript: all authors.

Conflicts of Interest

Seoung Ju Park is an associate editor of the journal, but he was not involved in the peer reviewer selection, evaluation, or decision process of this article. No other potential conflicts of interest relevant to this article were reported.

Funding

This study was supported by the Aju Pharm Co., Ltd., Seoul, Republic of Korea. The sponsor had no role in the design of the study, the collection and analysis of the data, or the preparation of the manuscript.

Supplementary Material

Supplementary material can be found in the journal homepage (http://www.e-trd.org).

Supplementary Table S1.

Study design: phases and scheduled assessment

trd-2025-0105-Supplementary-Table-S1.pdf

Supplementary Table S2.

Risk factors for acute exacerbation in patients with chronic obstructive pulmonary disease in study periods

trd-2025-0105-Supplementary-Table-S2.pdf

Supplementary Table S3.

Factors associated with increased frequency of acute exacerbation in patients treated with OM-85

trd-2025-0105-Supplementary-Table-S3.pdf

Supplementary Table S4.

Baseline characteristics according to CAT ≥10

trd-2025-0105-Supplementary-Table-S4.pdf

References

1. Global Initiative for Chronic Obstructive Lung Disease. Global Strategy for the Diagnosis, Management, and Prevention of Chronic Obstructive Pulmonary Disease: 2025 Report [Internet]. Deer Park; GOLD; 2024 [cited 2025 Oct 14]. Available from: https://goldcopd.org/2025-goldreport.

2. Park H, Jung SY, Lee K, Bae WK, Lee K, Han JS, et al. Prevalence of chronic obstructive lung disease in Korea using data from the fifth Korea national health and nutrition examination survey. Korean J Fam Med 2015;36:128–34.

3. World Health Organization. Global health estimates: projections of mortality and causes of death, 2015–2030. Geneva: WHO; 2018.

4. Pham HQ, Pham KH, Ha GH, Pham TT, Nguyen HT, Nguyen TH, et al. Economic burden of chronic obstructive pulmonary disease: a systematic review. Tuberc Respir Dis (Seoul) 2024;87:234–51.

5. Agusti A, Hogg JC. Update on the pathogenesis of chronic obstructive pulmonary disease. N Engl J Med 2019;381:1248–56.

6. Agusti A, Melen E, DeMeo DL, Breyer-Kohansal R, Faner R. Pathogenesis of chronic obstructive pulmonary disease: understanding the contributions of gene-environment interactions across the lifespan. Lancet Respir Med 2022;10:512–24.

7. Fang L, Zhou L, Tamm M, Roth M. OM-85 Broncho-Vaxom, a bacterial lysate, reduces SARS-CoV-2 binding proteins on human bronchial epithelial cells. Biomedicines 2021;9:1544.

8. Antunes KH, Cassao G, Santos LD, Borges SG, Poppe J, Goncalves JB, et al. Airway administration of bacterial lysate OM-85 protects mice against respiratory syncytial virus infection. Front Immunol 2022;13:867022.

9. Bessler WG, Vor dem Esche U, Masihi N. The bacterial extract OM-85 BV protects mice against influenza and Salmonella infection. Int Immunopharmacol 2010;10:1086–90.

10. Esposito S, Cassano M, Cutrera R, Menzella F, Varricchio A, Uberti M. Expert consensus on the role of OM-85 in the management of recurrent respiratory infections: a Delphi study. Hum Vaccin Immunother 2022;18:2106720.

11. Emmerich B, Pachmann K, Milatovic D, Emslander HP. Influence of OM-85 BV on different humoral and cellular immune defense mechanisms of the respiratory tract. Respiration 1992;59 Suppl 3:19–23.

12. Cvoriscec B, Ustar M, Pardon R, Palecek I, Stipic-Markovic A, Zimic B. Oral immunotherapy of chronic bronchitis: a double-blind placebo-controlled multicentre study. Respiration 1989;55:129–35.

13. Pan L, Jiang XG, Guo J, Tian Y, Liu CT. Effects of OM-85 BV in patients with chronic obstructive pulmonary disease: a systematic review and meta-analysis. J Clin Pharmacol 2015;55:1086–92.

14. Razi CH, Harmanci K, Abaci A, Ozdemir O, Hizli S, Renda R, et al. The immunostimulant OM-85 BV prevents wheezing attacks in preschool children. J Allergy Clin Immunol 2010;126:763–9.

15. Koatz AM, Coe NA, Ciceran A, Alter AJ. Clinical and immunological benefits of OM-85 bacterial lysate in patients with allergic rhinitis, asthma, and COPD and recurrent respiratory infections. Lung 2016;194:687–97.

16. Tang H, Fang Z, Saborio GP, Xiu Q. Efficacy and safety of OM-85 in patients with chronic bronchitis and/or chronic obstructive pulmonary disease. Lung 2015;193:513–9.

17. Soler M, Mutterlein R, Cozma G. Double-blind study of OM-85 in patients with chronic bronchitis or mild chronic obstructive pulmonary disease. Respiration 2007;74:26–32.

18. Orcel B, Delclaux B, Baud M, Derenne JP. Oral immunization with bacterial extracts for protection against acute bronchitis in elderly institutionalized patients with chronic bronchitis. Eur Respir J 1994;7:446–52.

19. Choi JY, Park YB, An TJ, Yoo KH, Rhee CK. Effect of Broncho-Vaxom (OM-85) on the frequency of chronic obstructive pulmonary disease (COPD) exacerbations. BMC Pulm Med 2023;23:378.

20. Collet JP, Shapiro P, Ernst P, Renzi T, Ducruet T, Robinson A. Effects of an immunostimulating agent on acute exacerbations and hospitalizations in patients with chronic obstructive pulmonary disease: the PARI-IS study steering committee and research group: prevention of acute respiratory infection by an immunostimulant. Am J Respir Crit Care Med 1997;156:1719–24.

21. Voll-Aanerud M, Eagan TM, Wentzel-Larsen T, Gulsvik A, Bakke PS. Respiratory symptoms, COPD severity, and health related quality of life in a general population sample. Respir Med 2008;102:399–406.

22. Sun T, Li X, Cheng W, Peng Y, Zhao Y, Liu C, et al. The relationship between morning symptoms and the risk of future exacerbations in COPD. Int J Chron Obstruct Pulmon Dis 2020;15:1899–907.

23. Miravitlles M, Ribera A. Understanding the impact of symptoms on the burden of COPD. Respir Res 2017;18:67.

24. Mun SY, Hwang YI, Kim JH, Park S, Jang SH, Seo JY, et al. Awareness of chronic obstructive pulmonary disease in current smokers: a nationwide survey. Korean J Intern Med 2015;30:191–7.

25. Parola C, Salogni L, Vaira X, Scutera S, Somma P, Salvi V, et al. Selective activation of human dendritic cells by OM-85 through a NF-kB and MAPK dependent pathway. PLoS One 2013;8e82867.

26. Mauel J, Van Pham T, Kreis B, Bauer J. Stimulation by a bacterial extract (Broncho-Vaxom) of the metabolic and functional activities of murine macrophages. Int J Immunopharmacol 1989;11:637–45.

27. Rahman MM, Grice ID, Ulett GC, Wei MQ. Advances in bacterial lysate immunotherapy for infectious diseases and cancer. J Immunol Res 2024;2024:4312908.

28. Criner GJ, Bourbeau J, Diekemper RL, Ouellette DR, Goodridge D, Hernandez P, et al. Prevention of acute exacerbations of COPD: American College of Chest Physicians and Canadian Thoracic Society Guideline. Chest 2015;147:894–942.

29. Hurst JR, Han MK, Singh B, Sharma S, Kaur G, de Nigris E, et al. Prognostic risk factors for moderate-to-severe exacerbations in patients with chronic obstructive pulmonary disease: a systematic literature review. Respir Res 2022;23:213.

30. Kong CW, Wilkinson TM. Predicting and preventing hospital readmission for exacerbations of COPD. ERJ Open Res 2020;6:00325–2019.

Article information Continued

It is identical to the Creative Commons Attribution Non-Commercial License (http://creativecommons.org/licenses/by-nc/4.0/).

Characteristic	Value
Total no.	323
Age, yr	73.3±7.8
Male sex	266 (83.9)
BMI, kg/m²	22.7±3.3
FEV1, % predicted	57.8±18.4
FVC, % predicted	75.6±18.4
FEF25–75, % predicted	29.7±13.7
DLCO, % predicted	66.1±21.8
Ever smoker	277 (85.8)
Previous history of TB^*	104 (32.2)
Co-morbid condition
Cardiovascular disease	153 (47.4)
Diabetes mellitus	75 (23.2)
Bronchiectasis	52 (16.1)
GERD	49 (15.2)
Asthmatic component	43 (13.3)
Concurrent medication
LABA+LAMA	193 (59.8)
LAMA	67 (20.7)
ICS+LABA	36 (11.1)
PDE4 inhibitor	19 (5.9)
Oral xanthines	60 (18.6)
Oral beta agonist	19 (5.9)
Baseline symptoms score
mMRC grade ≥2	144 (44.6)
CAT ≥10	126 (39.0)
SGRQ ≥25%	186 (57.6)
Previous history of AE	29/319 (9.1)

Measure	Time point	CAT <10	CAT ≥10	Group effect (F/Wald χ², df, p-value)	Time effect (F/Wald χ², df, p-value)	Time×Group (F/Wald χ², df, p-value)
CAT	Baseline	4.82±2.30	17.53±6.84	F=354.9, df=1, p<0.001	F=18.03, df=2, p<0.001	F=32.80, df=2, p<0.001
	3 months	4.98±3.31	15.07±8.13
	6 months	5.42±3.98	13.82±8.35
CAT responder^*	Baseline	-	-	χ²=30.5, df=1, p<0.001	χ²=11.6, df=1, p=0.001	χ²=0.10, df=1, p=0.749
	3 months	47/197 (23.9)	69/126 (54.8)
	6 months	58/197 (29.4)	79/126 (62.7)
mMRC	Baseline	1.24±0.59	2.16±0.99	F=111.15, df=1, p<0.001	F=0.71, df=2, p=0.492	F=2.47, df=2, p=0.086
	3 months	1.28±0.68	2.14±1.01
	6 months	1.29±0.69	2.03±0.99
SGRQ	Baseline	24.14±11.73	51.38±24.21	F=13.00, df=1, p <0.001	F=4.318, df=2, p=0.014	F=8.09, df=2, p<0.001
	3 months	24.89±13.42	47.71±25.96
	6 months	25.22±15.62	44.42±28.42
SGRQ responder^†	Baseline	-	-	χ²=15.7, df=1, p<0.001	χ²=10.5, df=1, p=0.001	χ²=4.6, df=1, p=0.032
	3 months	47/197 (23.9)	57/126 (45.2)
	6 months	57/197 (28.9)	59/126 (46.8)
Acute exacerbation	Baseline	0.08±0.29	0.14±0.39	F=8.412, df=1, p=0.004	F=6.88, df=2, p=0.001	F=0.034, df=2, p=0.966
	3 months	0.02±0.13	0.06±0.24
	6 months	0.01±0.11	0.06±0.25

Variable	Univariable analysis			Multivariable analysis
Variable	OR	95% CI	p-value	OR	95% CI	p-value
Age ≥65 years	1.953-E8	0.000	>0.999
Male sex	0.500	0.060–4.153	0.521
Ever smoker	1.871-E8	0.000	>0.999
BMI <18.5 kg/m²	2.518	0.596–10.636	0.209	4.016	0.819–19.682	0.086
Cardiovascular disease	1.445	0.416–5.022	0.563
Diabetes mellitus	3.080	0.862–11.000	0.083	3.844	0.977–15.128	0.054
Bronchiectasis	1.378	0.271–7.066	0.699
Asthma	1.183	0.292–4.788	0.814
Old TB	1.011	0.278–3.672	0.987
GERD	1.041	0.208–5.209	0.961
Inhaler
No inhaler use	Reference
LAMA	0.000	0.000	>0.999
LAMA+LABA	0.456	0.134–2.471	0.574
ICS+LABA	0.356	0.033–3.805	0.393
PDE4 inhibitor	0.000	0.000	>0.999
Oral xanthine	0.978	0.196–4.878	0.978
Oral beta agonist	2.060	0.219–19.409	0.528
FEV1, % predicted ≤50	1.042	0.300–3.621	0.949
mMRC ≥2	2.068	0.424–10.089	0.369
CAT responder at 3 months^*	0.714	0.197–2.584	0.608
CAT responder at 6 months^*	0.248	0.051–1.203	0.084
SGRQ ≥25%	2.141	0.293–19.912	0.413
SGRQ responder at 3 months^†	0.714	0.197–2.584	0.608
SGRQ responder at 6 months^†	0.248	0.051–1.203	0.084	0.218	0.043–1.108	0.066
Previous AE history	0.000	0.000	>0.999

System	Adverse drug reactions	Severity	Number
Respiratory	Pneumonia	Moderate	3
	Dyspnea	Moderate to severe	4
Gastrointestinal	Epigastric pain	Mild	2
	Constipation	Mild	1
	Enterocolitis	Moderate	1
Cardiovascular	Hypertension	Mild	2
	Palpitation	Mild	1
	Uremic pericarditis	Moderate	1
Neurological	Dizziness	Mild	1
	Tingling sense in legs	Mild	1
Skin	Urticaria	Moderate	1
	Itching sense	Moderate	1
Kidney	Acute kidney injury	Severe	1
Others	Decreased appetite	Mild	1
	General weakness	Mild	1
	Metastatic adenocarcinoma	Severe	1

Variable	Time	Number	Mean±SD	p-value
mMRC	Baseline	314	1.60±0.90
	3 months	314	1.62±0.93	0.593
	6 months	308	1.57±0.89	0.771
CAT	Baseline	319	9.81±7.79
	3 months	319	8.97±7.58	0.001
	6 months	319	8.69±7.35	0.001
SGRQ	Baseline	321	1,113.26±707.66
	3 months	321	1,082.19±712.96	0.234
	6 months	323	1,048.36±752.31	0.074
SGRQ%	Baseline	321	34.74±22.08
	3 months	321	33.78±22.25	0.234
	6 months	323	32.72±23.48	0.074
Symptoms	Baseline	321	45.25±19.54
	3 months	321	44.11±19.81	0.210
	6 months	323	42.04±20.29	0.004
Activity	Baseline	321	49.45±26.54
	3 months	321	47.83±27.66	0.167
	6 months	323	46.26±28.34	0.038
Impact	Baseline	321	22.41±24.74
	3 months	321	21.88±23.83	0.567
	6 months	323	21.48±25.32	0.467