Baseline Characteristics and Serum Immunoglobulin Levels in Patients with COPD
Compared with the control group of healthy middle-aged patients, we observed significantly lower serum IgG concentrations and subgroups in the COPD patient group (1150.6 vs. 2032.2 mg/dl), with the IgG1 concentration experiencing the greatest decline. Conversely, IgA levels in the COPD group were significantly higher than in the control group (133.8 compared to 45 mg/dl). There were no significant differences in IgM and IgE concentrations between the two groups. In the COPD group, 10.4% of patients exhibited decreased serum IgG concentrations compared to the normal reference threshold, while there were no cases of serum IgG deficiency in the control group. Notably, the rate of decreased serum IgG1 concentration in the COPD group was substantially higher at 73.1% compared to 3.3% in the control group. Similarly, decreased IgG3 was observed in 49.3% of the COPD group compared to 3.3% in the control group, and 43.3% of COPD patients had decreased IgG4 levels compared to 10% in the control group. Furthermore, 17.9% of COPD patients exhibited decreased IgA levels compared to 96.7% in the control group (p < 0.001). No cases of decreased IgM concentrations were recorded in either group. Additionally, we identified 2 cases (0.3%) of CVID within the COPD group.
Humoral immune defects are a spectrum of diseases that represent the most common primary immunodeficiency disorders. The adult antibody deficiency syndromes include CVID, selective IgA deficiency (SIgAD), and specific antibody deficiency (SAD). The prevalence of antibody deficiencies ranges from 1:500 in SIgAD to about 1:25,000 in CVID. About 32% of patients with CVID develop pneumonia, and about 23% develop bronchiectasis [15].
The likelihood of hypogammaglobulinemia increases with increased severity of COPD and is associated with increased mortality. IgG subclass deciency, especially IgG2 deciency, is also common in patients with COPD and IgG subclass levels correlate with poor outcomes. The cause for low immunoglobulin levels in patients with COPD is multifactorial including, possibly, the fact that oral corticosteroids may decrease IgG levels [16].
Genetic properties and smoking are involved in regulation of serum IgG concentration. Subtly low IgG levels among smokers strongly suggest cessation of smoking as the first line intervention. Respiratory infection burden associated with serum immunoglobulin concentration in the general population is poorly understood and, availability of IgG replacement products is currently limited, thus treatment of fully asymptomatic individuals need to appear prudent [7].
Studies on serum Ig concentrations have revealed significant fluctuations in Ig concentration thresholds, influenced by a myriad of factors, including immune response dynamics. In the context of chronic inflammation, interleukin-6 (IL-6) is recognized as a promoter of Ig synthesis. A study by A. Gonzalez Quintela (2008) among adults found average IgG concentrations at 1118 mg/dl, IgM at 147 mg/dl, and IgA at 262 mg/dl. Notably, IgA tends to be higher in men compared to women, while IgG and IgM levels are higher in women. Regarding age distribution, IgG and IgA concentrations were observed to gradually increase with age, with no significant difference in IgM concentrations across age groups. Furthermore, IgA concentrations exhibit a tendency to be higher in groups with obesity and metabolic disorders characterized by elevated glucose and blood fat levels, while no disparities were noted in IgG and IgM concentrations. These findings underscore the complex interplay of Ig concentrations with demographic and metabolic factors [17].
According to Williamson et al. (2014), normal serum Ig concentrations were as follows: IgG: 768–1632 mg/dl, IgM: 60–263 mg/dl, IgA: 82–453 mg/dl, IgE: 0.01–0.04 mg/dl [18]. Kim et al. (2016), concentrations of IgG subclasses are as follows: IgG1: 382.4–928.6 mg/dL, IgG2: 241.8–700.3 mg/dL, IgG3: 21.8–176.1 mg/dL, IgG4: 3.9–86.4 mg/dL [19].
According to Samea et al. (2011), there was a significantly higher increase in IgE levels in the serum of patients with stable and acute COPD compared to the control group. IgE concentrations were also higher and showed differences when comparing during and outside exacerbations of COPD. However, it was observed that bronchial asthma patients had increased serum IgE levels compared to the COPD group [20].
McCullagh et al. (2017), the study focused on changes in serum antibody levels and immune response with antibody replacement therapy in COPD patients experiencing ≥ 2 exacerbations/year. The results revealed that 69% of patients exhibited the common multiple immune deficiency syndrome. Among these patients, 27.6% had general antibody deficiency, 69% had specific antibody deficiency, and 3.4% had selective IgA deficiency [5].
In a study conducted by Pia Holma et al. in Finland, the mean serum IgG concentration among 5430 participants at age 46 years was 11.20 g/L. Two standard deviations below and above the mean were 6.84 g/L and 15.56 g/L, respectively. Among the participants, 57 had serum IgG levels of 6.8 g/L or lower, while 162 had levels above 15.6 g/L. IgG subclasses were measured for individuals with serum IgG levels lower than 5.0 g/L or higher than 20.0 g/L. In all cases, the subclass findings were consistent with an even distribution [7].
Several factors contribute to secondary immunodeficiency in COPD patients, with prominent ones supported by substantial evidence including prolonged exposure to cigarette smoke, extended use of corticosteroids, and nutritional deficiencies. Prolonged exposure to cigarette smoke, a significant risk factor for COPD development, can detrimentally affect immune function. Similarly, the extended use of corticosteroids, often prescribed to manage COPD exacerbations and inflammation, may suppress the immune system, increasing susceptibility to infections. Additionally, malnutrition and deficiencies in essential nutrients, common in COPD due to factors like reduced appetite and increased energy expenditure during breathing, can weaken the immune system, further exacerbating immunodeficiency in these patients. In this study, we observed a notable decrease in serum Ig concentrations among COPD patients compared to controls of similar race and age. This finding indicates that serum antibody deficiency is a prevalent condition in individuals with COPD. It is plausible that this deficiency contributes to the frequent exacerbations of the disease associated with respiratory infections.
Associations of Serum Immunoglobulin Concentrations with Clinical and Subclinical Characteristics in Group E COPD Patients
Our analysis of the relationship between serum Ig concentrations and various individual, clinical, and paraclinical characteristics revealed several key findings. Firstly, we observed that the average age of individuals with reduced IgG levels was higher compared to those with normal IgG concentrations (75.5 ± 7.9 vs. 71.1 ± 7.8 years old). Factors such as smoking history, disease duration, body mass index (BMI), and the modified Medical Research Council (mMRC) dyspnea scale score did not demonstrate a significant impact on the difference in IgG concentrations between the two groups. Additionally, no notable disparities were recorded in measures of airflow obstruction, including GOLD classification, forced expiratory volume in one second (FEV1%) and the ratio of FEV1 to forced vital capacity (FEV1/FVC%), between individuals with low and normal IgG levels (p > 0.05). However, there was a tendency for the chronic bronchitis phenotype to be more prevalent in the group with reduced serum IgG levels. Furthermore, parameters such as blood white blood cell count, albumin concentration, serum C-reactive protein (CRP), and procalcitonin (PCT) levels showed no significant differences between the two groups. Similarly, when examining the relationship between IgA levels and individual, clinical, and paraclinical characteristics, no statistically significant differences were noted.
In the study by Holm et al. (2020), no significant difference was observed in inflammatory parameters between two groups of COPD patients with antibody deficiency and those without serum antibody deficiency: CRP (5.2 mg/mL vs. 7.5 mg/mL) and white blood cells (9 x 10^9/L vs. 8.3 x 10^9/L) [21].
In a study conducted by Pia Holma et al., serum IgG concentrations were measured at age 46 years in a cohort of 5430 individuals. The results revealed an association between current smoking and low serum IgG levels in both males and females. Specifically, serum IgG concentrations were 10.3 g/L among current smokers and 11.5 g/L among non-smokers, indicating a significant difference (p < 0.001). However, the mean serum IgG concentration in former smokers did not differ from that of non-smokers [7].
In the study, we identified specific associations within subgroups of IgG concentrations. Firstly, in the group with low IgG1 concentrations, a higher proportion of patients were observed in GOLD stage 4 compared to the normal IgG1 concentration group (32.7% vs. 11.1%). Additionally, the serum procalcitonin (PCT) concentration in the low IgG1 concentration group was significantly higher than in the normal IgG1 group (0.1 ± 0.2 vs. 0.8 ± 1.9 ng/ml). Furthermore, individuals with low IgG2 levels exhibited a significantly higher average age compared to the normal group (76.8 ± 6.7 vs. 70.6 ± 7.8 years). Additionally, the duration of disease in the low IgG3 group was significantly longer compared to the normal group (7.6 ± 6.3 vs. 5.1 ± 2.9 years). However, no statistically significant relationships were found between the remaining factors and the concentration of IgG subgroups.
Antibodies are crucial components of the body's adaptive immune system, providing defense against pathogens. Complete or partial deficiency in these antibody classes can increase the risk of various infectious diseases. Among these, IgG holds particular importance, constituting 70–80% of total serum antibodies and serving as a primary defense mechanism against extracellular threats. IgG is further divided into four subclasses, each with distinct roles in immune defense. IgG1 is primarily involved in combating protein-derived antigens, while IgG2 contributes to resistance against microbes with polysaccharide coatings. IgG3 plays a critical role in the immune response against respiratory viruses, and IgG4 is particularly important in fighting respiratory infections [14]. Indeed, it's crucial to emphasize that serum antibody deficiency doesn't always equate to immunodeficiency. Even if an individual has slightly reduced total antibody levels, their body may still be capable of mounting a specific immune response tailored to combat particular pathogens. This highlights the complexity of the immune system, where various factors beyond serum antibody levels contribute to overall immunity and defense against infections [10].
During the longitudinal follow-up spanning 12 months, we observed that the group with low serum IgG levels experienced a higher frequency of exacerbations per year compared to the normal group (3.4 ± 1.5 vs. 2.9 ± 1). Similarly, the group with high serum IgE levels also had exacerbations occurring more frequently than the normal group (3.2 ± 1.1 vs. 2.9 ± 1). However, we found no significant differences between the two groups in terms of the phenotype of multiple exacerbations and the frequency of exacerbations requiring hospitalization.
Indeed, immune deficiencies, particularly IgG deficiencies, are linked to recurrent infections in patients with chronic airway diseases like bronchial asthma, COPD, or bronchiectasis. IgG3, comprising about 2–4% of total serum IgG, is the most frequently observed subclass deficiency in chronic airway diseases and is closely associated with the risk of recurrent infections and exacerbations. It's important to note that an individual may experience a deficiency in one IgG subclass without a general IgG deficiency, or they may have a combined deficiency of multiple subclasses. This highlights the complexity and variability of immune responses in these conditions [19], [22].
In a study conducted by Kim et al. (2016) in Korea involving 59 adult patients with bronchial asthma and COPD, the findings revealed that IgG3 deficiency was the most prevalent (88.1%), followed by IgG4 deficiency (15.3%). Common infectious complications observed included pneumonia (60.2%), recurrent bronchitis (15.9%), and sinusitis (12.5%), with a lower incidence of extrapulmonary infections. Pus bacillus was identified as the primary cause of pneumonia, followed by Klebsiella pneumoniae, pneumococcus, and Moraxella catarrhalis. These findings underscore the significance of IgG subclass deficiencies in predisposing individuals with chronic airway diseases to recurrent infections, highlighting the importance of targeted interventions and management strategies [19].
In the study conducted by Leitao Filho et al. (2018), it was found that 18.8% of patients exhibited a deficiency in at least one IgG subclass. The incidence of decreased IgG1-4 subclasses was 4.5%, 5.7%, 7.6%, and 7%, respectively. Notably, simultaneous reduction of two or more subclasses ranged from 0.2–2.9%. Differences were observed in the decline of IgG1 and IgG2 levels between the group with two or more exacerbations compared to the group with one or fewer exacerbations. Additionally, 25% of moderate and severe COPD patients experienced a decline in IgG levels. Specifically, it was observed that up to 50–100% of these individuals exhibited a phenotype characterized by frequent exacerbations and a high likelihood of hospitalization due to exacerbations. These findings underscore the importance of evaluating IgG subclass levels in COPD patients, especially those with a history of exacerbations, to better understand and manage their disease progression [23].
The role of defective adaptive immunity and low serum immunoglobulin (IgG) concentration is well established in CVID (CVID) patients suffering from recurrent pneumonia and respiratory tract complications. It has also been shown that patients with milder forms of hypogammaglobulinemia may suffer from respiratory infections. Although these patients benefit from IgG replacement therapy, they may remain fully asymptomatic for years. Early diagnosis and consideration of IgG replacement therapy is believed to be beneficial. Not only low but even high serum IgG concentrations were associated with respiratory infection burden. Elevated serum IgG in older individuals may also indicate risk of pneumonia-related mortality and recurrent pneumonia although mechanisms are incompletely described [7].
In a retrospective analysis by Cowan et al. (2015), involving 14 cases of COPD patients with serum antibody deficiency who underwent antibody replacement therapy, the authors reported a reduction in the frequency of moderate and severe exacerbations. This suggests that antibody replacement therapy may be beneficial in managing COPD patients with serum antibody deficiency, potentially mitigating the recurrence of exacerbations and improving disease outcomes [11].
In a study by Bermejo Martin et al. (2014), the association between serum Ig deficiency and death due to infection was investigated in 172 patients. The findings revealed that concomitant deficiencies in IgG1, IgM, and IgA were associated with an increased risk of death in patients with severe sepsis or septic shock. These results suggest that supplementing exogenous Ig may aid in improving treatment outcomes in patients with severe sepsis, particularly in cases where multiple Ig deficiencies are present. This highlights the potential importance of tailored immunomodulatory therapies, such as Ig adjuvant therapy, in managing severe infections and improving patient survival [24].
Indeed, the existing literature on the prognostic role and exacerbation frequency associated with decreased IgG levels in COPD remains limited and somewhat inconclusive. Different studies present varying perspectives on this issue [7], [16], [25], [26]. There is currently insufficient strong evidence to confirm a clear relationship between decreased IgG concentrations and exacerbation frequency or to establish the prognostic value of IgG concentrations regarding exacerbation risk. This uncertainty stems from the influence of numerous factors on serum IgG concentration, such as malnutrition and prolonged corticosteroid use in treatment. Further research is needed to elucidate the complex relationship between IgG levels and exacerbation risk in COPD, considering the multifactorial nature of this condition and its management [27].
In our study, we did not investigate the relationship between serum Ig levels and the frequency or risk of exacerbations. This finding may be due to the small sample size of our study. Additionally, the recurrence rate of acute exacerbations is influenced by various factors such as patient treatment compliance, quality of care, and disease management conditions. Furthermore, all patients in our study belonged to group E, with Ig concentrations lower than the average threshold of the control group. Therefore, no significant differences were observed when comparing factors within the COPD group. Moreover, the severity of exacerbations is affected by multiple factors, including disease stage, degree of airflow obstruction, and co-morbidities, rather than solely by infections related to Ig deficiency. These factors collectively contribute to the complexity of exacerbation outcomes in COPD patients.
It's important to acknowledge the limitations of our study. Firstly, being a single-center study, the generalizability of our findings may be limited. Secondly, the sample size utilized in the study was relatively small, and it included only COPD patients in group E. Therefore, our findings offer initial insights into the characteristics of serum Ig concentrations in group E COPD patients and their association with clinical and paraclinical characteristics and future exacerbation risk. Further research with larger sample sizes, multicenter studies, inclusion of patients across various disease stages, and longer follow-up periods are needed to comprehensively evaluate changes in serum Ig concentrations and exacerbation risk in COPD patients. Subsequent studies can inform specific recommendations for the use of IVIG therapy in COPD treatment.