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Risk factors associated with the presence of irreversible airflow limitation and reduced transfer coefficient in patients with asthma after 26 years of follow up
  1. J M Vonk1,
  2. H Jongepier2,
  3. C I M Panhuysen3,
  4. J P Schouten1,
  5. E R Bleecker4,
  6. D S Postma5
  1. 1Department of Epidemiology and Statistics, University of Groningen, The Netherlands
  2. 2Beatrixoord Hospital, Haren, The Netherlands
  3. 3Boston University Schools of Medicine and Public Health, Boston, MA, USA
  4. 4University of Maryland, Baltimore, Maryland, USA
  5. 5Department of Pulmonology, University Hospital Groningen, The Netherlands
  1. Correspondence to:
    Professor D S Postma, Department of Pulmonology, University Hospital, Hanzeplein 1, 9713 GZ Groningen, The Netherlands;
    d.s.postma{at}int.azg.nl

Abstract

Background: Childhood asthma is generally believed to be a disorder with a good prognosis. However, some asthmatics develop irreversible airway obstruction, probably as a result of airway remodelling.

Methods: After 21–33 years, 228 adults (aged 13–44 years at baseline) with a history of asthma were re-examined to assess risk factors for the development of irreversible airway obstruction (IAO, forced expiratory volume in 1 second (FEV1) <80% predicted and reversibility <9% predicted) and a reduced postbronchodilator transfer coefficient (carbon monoxide transfer factor/alveolar volume, <80% predicted), both characteristics of COPD.

Results: At follow up, 41% did not have airway obstruction (NAO), 43% had reversible airway obstruction (RAO), and 16% had IAO; 23% had a reduced transfer coefficient. Patients with RAO had asthma-like characteristics (wheezing, asthma attacks, bronchial hyperresponsiveness (BHR)) while patients with IAO had COPD-like symptoms (cough, phlegm, dyspnoea) at follow up. The development of IAO is determined by a lower FEV1, less reversibility of airway obstruction and, surprisingly, less severe BHR at initial screening. Eighty percent of the patients with asthma who used anti-inflammatory medication still had airway obstruction, but IAO developed less frequently. Smoking was associated with a reduced transfer coefficient but not with the development of IAO. Female sex was associated with a reduced transfer coefficient, whereas corticosteroid use was not.

Conclusions: Although IAO and a low transfer coefficient are both characteristics of COPD, they represent distinct entities in adult asthmatics in terms of symptomatology, aetiology, and probably in therapeutic approaches and disease prevention.

  • asthma
  • irreversible airway obstruction
  • transfer coefficient

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Childhood asthma is generally believed to be a disorder with a good prognosis. When only asthma symptoms are taken into account, almost 50% of children with asthma will be asymptomatic when reaching adulthood.1–4 However, many of these asymptomatic adults with a history of childhood asthma have persistent bronchial hyperresponsiveness, with or without airway obstruction.2,5 Furthermore, a considerable relapse rate has been reported in subjects thought to have outgrown their asthma.6 Prospective studies comparing adult asthmatics with non-asthmatics have shown a faster decline in forced expiratory volume in 1 second (FEV1) in those with asthma7–9 which may lead to persistent and progressive airway obstruction.10

Although several risk factors for ongoing disease activity from childhood to adulthood are reported in the literature, only a few prospective studies have been published identifying risk factors for the development of irreversible airway obstruction (IAO) in patients with asthma. Ulrik and Backer11 conducted a 10-year follow up study in 92 non-smoking adult asthmatics and found that a higher degree of bronchodilator reversibility at enrolment and long term treatment with oral corticosteroids were associated with IAO at follow up. Other studies have shown that the duration of asthma and the severity of the disease are associated with IAO.12–14 IAO is compatible with a diagnosis of chronic obstructive pulmonary disease (COPD). Since previous studies have shown that it may also occur in patients with chronic asthma, other patient characteristics are needed to separate asthma from COPD if irreversibility exists in older individuals. One characteristic that may separate asthma from COPD is a reduced transfer coefficient (Kco) which has been associated with the presence of emphysema.15

In the present study a cohort of patients with asthma treated between 1962 and 1970 were restudied after a follow up period of 21–33 years with the aim of identifying risk factors for the development of IAO and reduced Kco.

METHODS

Study design

Two hundred and twenty eight patients with asthma admitted to the asthma clinic at Beatrixoord Hospital in Haren, The Netherlands between 1962 and 1970 (visit 1) were re-examined between 1991 and 1998 at the same clinic (visit 2). Inclusion criteria at visit 1 were: age <45 years, a 20% fall in FEV1 during a histamine challenge test, no IAO, and clinical symptoms of asthma according to current ATS criteria.16,17 Exclusion criteria were the presence of specific respiratory disease (such as cystic fibrosis or tuberculosis) or any other serious interfering disease. At both visits the patients had to be in a stable condition without an exacerbation in the previous 6 weeks.

The study was approved by the medical ethics committee of the University Hospital Groningen and participants gave their informed consent.

During both visits a questionnaire on respiratory symptoms, lung function test, histamine challenge test, and allergen skin tests were performed.2 The transfer coefficient (Kco, carbon monoxide transfer factor (Tlco)/alveolar volume (Va)) was assessed at visit 2 only. Tlco was measured by the single breath method (Masterlab Transfer System; Jaeger, Würzberg, Germany), corrected for the haemoglobin level in peripheral blood and divided by Va.

Statistical analysis

IAO was defined as a prebronchodilator FEV1 of <80% predicted, improving by <9% predicted after administration of 800 μg salbutamol (albuterol). Reversible airway obstruction (RAO) was defined as a prebronchodilator FEV1 of <80% predicted, improving by ≥9% predicted after administration of salbutamol. No airway obstruction (NAO) was defined as a prebronchodilator FEV1 of ≥80% predicted. Reduced Kco was defined as a postbronchodilator Tlco/Va of <80% predicted. The untreated period from the onset of symptoms was defined as the time between the onset of asthma symptoms as reported in the questionnaire at visit 1 and the first treatment of the disease at Beatrixoord (visit 1). Smoking was defined as life time smoking in pack years (number of years a subject smoked 20 cigarettes/day). A subject was considered allergic when at least one positive (≥5 mm) allergen skin test was present.

A comparison of the characteristics of patients with NAO, RAO and IAO was first performed using one-way analysis of variance (for normal distributions), the Kruskal-Wallis test (for non-normal distributions), or a χ2 test (for categorical variables). If these tests indicated a difference between the three groups, group-by-group comparisons were performed with a Student's t test, Mann-Whitney U test, or χ2 test as appropriate. These tests were also used to compare the characteristics of patients with a reduced Kco with those of patients with a normal Kco.

Multiple logistic regression analyses were performed on the presence of IAO and on the presence of a reduced Kco at visit 2. Only patients who had airway obstruction at visit 2 were included in the analysis of IAO. The parameters included for visit 1 were: prebronchodilator FEV1 (% predicted), BHR as ln(slope), reversibility to a bronchodilator (ΔFEV1 as % FEV1 predicted), allergy status, duration of the untreated period (in years), and sex (female=0, male=1). For visit 2 the parameters included were age (in years), pack years of smoking, and the use of corticosteroids (oral and/or inhaled).

RESULTS

Patient characteristics

Between 1962 and 1970, 430 patients referred to Beatrixoord Hospital fitted the inclusion criteria. Of these, 202 (47.0%) were not available for visit 2: 11 (2.6%) had serious concomitant diseases, 26 (6.0%) were reported to be dead, 64 (14.9%) refused to participate in the study, 48 (11.2%) could not be located, and 53 (12.3%) were not approached because of time constraints. A total of 228 patients therefore participated in the study.

Table 1 shows that the non-participants were older, had a higher prevalence of smoking, and were less likely to be allergic at visit 1 than the participating subjects. There were no other significant differences between the participants and non-participants. The last column of table 1 shows the characteristics of the participants at the follow up visit. The median time to follow up was 26 years (range 21–33). At visit 2 bronchial hyperresponsiveness (BHR) was less severe and 15.7% of the patients no longer had BHR. The percentage of smokers fell from 36.8% to 26.8% during the follow up period and the percentage of allergic individuals fell from 94.3% to 82.5%. Prebronchodilator FEV1 % predicted values increased during the follow up period but postbronchodilator FEV1 % predicted values fell. This is also reflected in a lower degree of reversibility at visit 2.

Table 1

Characteristics of non-participating and participating patients (n=430).

Airway obstruction and irreversible airway obstruction

At follow up (visit 2) 93 of the 228 participants (41.3%) had no airway obstruction (NAO), 97 (43.1%) had RAO, and 35 (15.6%) had IAO (table 2). Three patients were excluded from the analysis because of missing lung function data at visit 2. The patients with NAO were significantly younger than those with RAO or IAO and they had a shorter untreated period. At visit 2 the prevalence of allergy was significantly higher in the NAO group than in those with IAO. The FEV1 % predicted and FEV1%IVC in patients with NAO both before and after bronchodilator were significantly higher than in the other groups at both visits.

Table 2

Characteristics of subjects stratified by airway obstruction and reversibility at visit 2 (n=225)

The postbronchodilator FEV1 % predicted at both visits was significantly higher in the RAO group than in the IAO group, while the prebronchodilator FEV1 % predicted did not differ between these groups. Reversibility at both visits was highest in the RAO group and differed significantly from the other groups. The RAO group also had the steepest slopes in the BHR test; at visit 1 the BHR slope in the RAO group was significantly steeper than in the NAO group while at visit 2 this slope was significantly steeper than in both the IAO and NAO groups. Patients with NAO used fewer asthma medications than the other groups at visit 2. Patients with IAO used fewer asthma medications at visit 2 than patients with RAO, which was primarily because fewer inhaled corticosteroids were used by the IAO group. There were no differences between the three groups in sex, age of onset of asthma, or smoking habits at both visits, nor in IgE levels and the proportion with reduced Kco at visit 2.

Figure 1 shows the percentage of patients reporting symptoms at visit 2 in the three groups. The NAO group reported fewer symptoms at visit 2, the RAO group reported more wheezing and current asthma attacks than the other groups, while the IAO group reported more symptoms of cough, phlegm and dyspnoea.

Figure 1

Percentage of subjects with respiratory symptoms at visit 2. Subjects stratified by airway obstruction and reversibility (n=225). No airway obstruction=prebronchodilator FEV1 ≥80% predicted; reversible airway obstruction=prebronchodilator FEV1 <80% predicted and reversibility ≥9% predicted; irreversible airway obstruction=prebronchodilator FEV1 <80% predicted and reversibility <9% predicted; cough=cough daily for at least 3 months a year; phlegm=bringing up phlegm daily for at least 3 months a year; dyspnoea=shortness of breath when walking at regular pace; wheeze=wheeze on almost every day or night; attacks=one or more asthma attacks in the previous 3 years. *p<0.05 v group with no airway obstruction; #p<0.05 v group with reversible airway obstruction; ‡p<0.10 v group with reversible airway obstruction

The results of the multiple logistic regression analyses are shown in table 3. The IAO group had significant ORs for prebronchodilator FEV1 (% predicted) at visit 1 (OR 0.95, 95% CI 0.92 to 0.98), ln(slope BHR) at visit 1 (OR 0.64, 95% CI 0.41 to 1.00), reversibility (% predicted) at visit 1 (OR 0.96, 95% CI 0.91 to 1.00), and the use of corticosteroids at visit 2 (OR 0.22, 95% CI 0.07 to 0.64). No significant effects were observed for age, sex, pack years of smoking at visit 2, allergy at visit 1, and the duration of the untreated period.

Table 3

Odds ratios (OR) and 95% confidence intervals (95% CI) of multiple logistic regression analyses on irreversible airway obstruction (FEV1 prebronchodilator <80% predicted and FEV1 reversibility <9% predicted at visit 2, only patients with prebronchodilator FEV1 <80% predicted included) and on a reduced postbronchodilator transfer coefficient ( kco, <80% predicted, all patients included)

Reduced transfer coefficient

Because of technical problems in the procedures, postbronchodilator Kco could not be tested in four patients at visit 2. In another 59 patients Kco was not measured because of a change in the protocol. Thirty eight of 165 patients (23.0%) had a reduced Kco after bronchodilation. Patients with reduced postbronchodilator Kco had a significantly higher total lung capacity (TLC) at visit 2 and a higher residual volume (RV) at both visits (table 4). At both visits the prevalence of smoking was higher in the group with a reduced Kco, although the difference was only significant at visit 1. Patients with a reduced Kco had smoked a greater number of pack years at visit 2. Significantly more women had a Kco of <80% predicted than men. There were no significant differences in age, age at onset of asthma, untreated period, allergic status at both visits, serum total IgE at visit 2, BHR at both visits, FEV1 and VC at both visits, reversibility at both visits, and medication use at visit 2. There were also no significant differences in the number of symptoms reported between the two groups (fig 2).

Table 4

Characteristics of subjects stratified by reduced post-bronchodilator carbon monoxide transfer coefficient (Kco) at visit 2 (n=165)

Figure 2

Percentage of subjects with respiratory symptoms at visit 2. Subjects stratified by reduced transfer coefficient (Kco (tlco/va) after bronchodilator <80% predicted) at visit 2 (n=165). Definition of symptoms as in fig 1.

Multiple logistic regression analysis (table 3) showed that men had a lower risk of having a reduced Kco than women (OR for men 0.33 (95% CI 0.14 to 0.80)). Patients who had smoked a higher number of pack years at visit 2 were more at risk of having a low Kco (OR 1.04, 95% CI 1.01 to 1.07). No significant effects were observed for age, prebronchodilator FEV1 (% predicted) at visit 1, BHR at visit 1, reversibility at visit 1, allergy at visit 1, the untreated period, and the use of corticosteroids at visit 2.

An additional multiple logistic regression analysis including RV and TLC at visit 1 showed that these parameters were not independent risk factors for a low Kco at follow up, while the estimates of sex and smoking were unchanged. An analysis of the interaction between sex and smoking included in the model did not change the results.

DISCUSSION

In a large cohort of 228 subjects with asthma studied extensively 21–33 years previously, approximately 16% developed IAO, 43% had retained their airway reversibility, and the remaining 41% had no evidence of airway obstruction. The development of IAO was associated with a lower FEV1 (% predicted), a lower level of BHR, less reversibility at initial testing, and with less use of corticosteroids at follow up; 23% had a reduced postbronchodilator Kco at visit 2. Female sex and a higher number of pack years were independent risk factors for having a reduced Kco. Only nine subjects (5% of all subjects) had both IAO and a reduced Kco at follow up, both features being compatible with a diagnosis of COPD.

Airway obstruction and irreversible airway obstruction

Subjects with NAO at follow up had less severe asthma at initial testing than those with either RAO or IAO—that is, better lung function and less severe BHR. At visit 2 these patients were less hyperresponsive, used less medication, and reported fewer symptoms (fig 1) than either the groups with RAO or IAO. At visit 2 the patients with RAO had the classic symptoms of asthma (reversible airway obstruction (by definition), BHR, symptoms of wheeze, and recent asthma attacks) more often than those in the IAO group. In contrast, the IAO group more often exhibited COPD-like symptoms (cough, phlegm and dyspnoea) but used less medication—particularly inhaled corticosteroids—than the RAO group.

Traditionally, asthma has been thought of as a disease characterised by RAO. However, it is acknowledged that asthma can evolve into IAO, probably as a result of airway remodelling caused by chronic inflammation of the airways.18 Our results suggest that an irreversible component of asthma is more likely to appear when FEV1 at first testing is low, when the severity of BHR is low, and when reversibility at first testing is low. The use of corticosteroids (inhaled and/or oral) may prevent the development of this irreversible component. Since 50% of the patients with IAO in our study did not use corticosteroids, it is possible that anti-inflammatory treatment might have prevented this irreversible component. In contrast, the observation that 89 of the 112 patients (80%) treated with corticosteroids at visit 2 still had airway obstruction suggests that this treatment does not prevent a progressive decline in lung function in most patients with asthma. Another explanation may be that the introduction of inhaled corticosteroids was delayed too long after the start of the disease. Selroos et al19 suggested that early treatment of asthma with an inhaled steroid may prevent patients from developing chronic airway obstruction. Most of the patients in our study had asthma for more than 15 years at the time inhaled corticosteroids became available in The Netherlands (in 1974). This may have resulted in functional and structural changes in the airways due to ongoing inflammatory processes, thereby causing a faster deterioration in lung function and ultimately resulting in irreversible airway obstruction.

Ulrik and Backer11 performed the only other longitudinal study to examine early risk factors for the development of IAO in patients with asthma. In contrast to our results, they found that a higher degree of bronchodilator reversibility at enrolment was associated with IAO at follow up. This may be explained by a longer duration of follow up in our study, or by differences in the study group (Ulrik and Backer included only non-smokers and they were older than our study group), or by the way in which reversibility at enrolment was determined. Ulrik and Backer measured reversibility 15 minutes after inhalation of 5 mg salbutamol while we measured it after an intramuscular injection of 25 mg thiazinamium methylsulphate, a very potent anticholinergic drug with antihistamine properties. Although the bronchodilating capacity of thiazinamium methylsulphate in asthma is without doubt,20,21 the comparability of the bronchodilating response to intramuscular thiazinamium sulphate and inhaled salbutamol has not formally been tested; this response may not be comparable both because of the type of drug and the route of administration.

Other studies have shown that a longer duration of asthma and more severe disease are associated with IAO.12–14 In the present study the duration of asthma at visit 2 was not associated with the development of an irreversible component of the airway obstruction. This can be explained by the fact that the duration of asthma is strongly associated with the level of lung function at visit 1. Excluding FEV1 at visit 1 from the analysis resulted in a significant effect of the duration of asthma on the presence of IAO at visit 2. However, in our study the duration of asthma at visit 1 was equivalent to the time since onset of asthma and the start of treatment. The duration of asthma therefore also reflects the delay in treatment. We suggest that the development of IAO is caused by a longer delay in treatment rather than by a longer duration of the disease.

The severity of BHR at first testing seemed to be protective against the development of IAO. This could be caused by airway remodelling. Researchers are not sure about the consequences of airway remodelling on the level of BHR, but it has been suggested that either BHR gets worse or that airway remodelling protects against exaggerated airway narrowing.22 The findings that less BHR and less reversibility at first testing are both associated with the development of IAO suggest that airway remodelling had already started 26 years ago. Because both BHR and reversibility are highly correlated with FEV1, we repeated the analysis without FEV1. This resulted in a lower estimate of both BHR and reversibility in childhood but, although they still had the same sign, these estimates were no longer significant. We therefore have to be cautious in interpreting these estimates. Only a few studies have investigated the effect of BHR in childhood on the level of reversibility or the level of lung function in adulthood, and the results are conflicting with some studies reporting no association23,24 and others reporting a positive association.1

Reduced transfer coefficient

Lynch and colleagues25 have shown that asthma patients who smoke more frequently have evidence of emphysema, as assessed by high resolution CT scanning, than patients with asthma who do not smoke. We used a reduced Kco as a marker which is highly correlated with the presence of emphysema on a CT scan. Comparison of the group with a reduced post-bronchodilator Kco and the group with a (near) normal Kco supported the findings of Lynch et al.25 The group with a reduced Kco included individuals with longer smoking histories. This group had a significantly higher RV and TLC at visit 1, which suggests that emphysematous changes could have started early in the course of obstructive lung disease. At that time there were already more smokers among the patients with a reduced Kco than in those in whom Kco was not reduced (52.6% v 33.1%). A striking finding was that significantly more women had a tlco/va of <80% predicted at visit 2. This was not caused by a greater susceptibility of women to the effects of smoking, as suggested by Xu et al,26 because the interaction between smoking and sex was not significant.

Our results suggest that patients with more severe asthma have a higher risk of developing IAO. Patients with asthma who had smoked more pack years were at a higher risk of developing subsequent reductions in Kco. In this group with airway obstruction a low FEV1, less severe BHR, and lower bronchodilator reversibility at initial testing is associated with a higher risk of developing an irreversible component of airway obstruction 26 years later. Although the start of anti-inflammatory treatment in this population was late, it seems that the development of an irreversible component of airway obstruction can be prevented or at least delayed by this medication, even at this stage of asthma. Signs of emphysema (low Kco) were found in a small subset of patients, particularly in those with a higher number of pack years and in women. Neither low FEV1 at initial testing nor the use of corticosteroids were associated with a reduced Kco at follow up. Finally, patients with IAO were more likely to report cough, dyspnoea, and phlegm and those with RAO reported more wheeze and asthma attacks. The number of symptoms in the groups with a high or low Kco were comparable.

Although both IAO and reduced Kco are characteristics of COPD, they seem to represent two distinct groups with regard to symptomatology, aetiology, and approach to treatment in this population of patients with asthma.

Acknowledgments

This study was supported by a grant from the Dutch Asthma Foundation. The authors also acknowledge financial support from the “Astma Bestrijding” and “De Kock Stichting” Foundations, and thank Mr E Gankema for his technical support.

REFERENCES